ASSESSMENT OF THE ROLE OF SOE STRUCTURE AND WATER CONTENT
IN THE INTEWRETATION OF
SPATIAL VARIATION IN YXELD AND YIELD RESPONSE TO NfLnOGEN
A Thesis
Presented to
The Faculty of Graduate Studies
of
The University of Guelph
by
JUSTIN TO
In partial fulfillment of requirements
For the degree of
Master of Science
Noveniber, 2000
O Juçtin To, 2000 National Library Bibliothèque nationale 1*1 of Canada du Canada Acquisitions and Acquisitions et Bibliographie Services services bibliographiques 395 Wellington Street 395, rue Wellington OttawaON K1AON4 Ottawa ON KIA ON4 Canada Canada Your file Votre référence
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The author retains ownership of the L'auteur conserve la propriété du copyright in this thesis. Neither the droit d'auteur qui protège cette thèse. thesis nor substantial extracts fiom it Ni la thèse ni des extraits substantiels may be printed or otherwise de celle-ci ne doivent êbe imprimés reproduced without the author's ou autrement reproduits sans son permission. autorisation. ASSESSMENT OF THE ROLE OF S01L ÇTRUCTLJRE AND WATER CONTENT IN THE INTERPRETATION OFSPATIAL VARIATION IN MELD AND YIELD RESPONSE TO NITROGEN
Justin To Advisor: University of Guelph, 2000 Dr. B.D. Kay
The Least Lirniting Water Range (LLWR), is defined as the range of water contents in which aeration, water and soii resistance are the least lirniting for plant growth. It was hypothesized that the LLWR and water contents measured outside of the LLW R would explain much of the variation found in yield and yieid response to fertilizer N. Water contents, soi1 properties and yields were measured on 12 sites across southem Ontario. Results showed that the LLWR parameters were poor predictors of the variability in yields. Many observed water contents were aiso found to be Iess than the wilting point. Kay et al. (1999) dehed a lower water content limit based on the cessation of photosynthesis (04.This study determined that the difference between water contents and 90, (plant extractable water) correlated well with yield. Organic carbon was significantly correlated to yield and yield response, and improved yields under drought and saturated conditions. ACKNOWLEDGEMENTS
1 would l&e to sincerely thank Dr. Bev Kay for his great support and guidance during the course of this study, as weU as the members of my conimittees, Dr. Tollenaar, Dr. Beauchamp, Dr. O'Halloran, Dr. Chesworth and
Dr. Groenevelt.
1would also like to thank al1 the fams that made my research possible,
Doug Aspinaii of OMAFRA, Mr. McCracken, Podolinksi Farms, Canagra Farms,
Mr. Caiiieron, Mr. Denys, Mr. Newconibe, the Elora Research Centre and the
Corn Producers of Ontario.
Finally, 1would like to extend special thanks to Chris McNabb, Leslie
Veale, Lisa Levesque, Chris Chroniiak, Matt Firth, Etienne Bilz, Jen Campbell,
Soo Kim, Ione Smith, Nathaniel Novosad, Andrew Wood, Co- Roberts and of iourse, Ranee Pd rardjdsing hani, Dr. Fallow and Jim Ferguson. TABLE OF CONTENTS
ACKNO W LEDGMENTS ...... i
LIST OF TABLES ...... iv
LIST OF FIGURES...... vi
LIST OF ABBREVLATIONS-...... x
CHAPTER 1: INTRODUCTION ...... 1
1.1 Background ...... 1 1.2 Objectives ...... 4 1.3 Format of Tliesis...... 5 1-4 References...... 6
CHAM-ER 2: USING PEDOTRANSFER FUNCTIONS TO PREDICT THE WATER RELEASE CURVE AND THE SOIL RESISTANCE CURVE...... 7
Introduction...... 7 Materials and Methods...... 10 Results and Discussion ...... 14 Coriclusioi~s...... 39 References ...... 41
CHAPTER 3: THE SENSTTIVITY OF CORN (Zea mays) MELD TO THE LEAST LIMITING WATER RANGE OF SOIT3...... 53
3.1 Introduction ...... 53 3.2 Materiais and h4ethods ...... 56 3.3 Results and Discussion ...... 59 3.4 Conclusions...... 75 3.5 References ...... 77 CHAPTER 4: UNDERçTANDING YIELDS OF CORN (Zeamays) AND ITS RELATIONSHiP WZTH PLANT EXTRACTABLE WATER AND SOIL PROPERTES ...... - ...... 79
4.1 Introduction ...... 79 4-2 Materids and Methods ...... -...... 84 4.3 Resdts and Discussion...... 87 4.4 Conciusions ...... 104 4.5 References...... 105
CHAM'ER 5: UNDERSTANDING THE VARL4BILICTY OF YIELD RESPONSES OF CORN TO NlTTROGEN FERTILIZER ACROSS RANGES OF WATER AND SOIL CHARACTERISTICS ...... 107
5.1 Introduction...... 107 5.2 Materials and Methods ...... 109 5-3 Resul ts and Discussion ...... 112 5.4 Conclusions ...... 124 ..... 5.5 References...... 126
CHAPTER 6: GENERAL CONCLUSIONS...... 130 LIST OF TABLES
Table 2.1. Summary of soil properties for all plots in each site (0-30cm depth)...... -15
Table 2-2. Mode1 forriis fitted to the measured water release data (385 cores wi th 3412 data points overall)...... 17
Table 2.3. Results of niodel fits to measured water release da ta...... 22
Table 2.4. Mode1 fornu fitted to measured soil resistance to penetration data (first data set of 321 cores) ...... 29
Tn ble 2-5. Results of niodel fits to measured soil resistd nce to penetra tion data (first data set)...... 33
Table 2-6. Paranieter estiiiiates for the Sand water release curve function...... 44
Table 2-7- Parameter es tinia tes for the Clav wa ter release curve function ...... 45
Table 2.8. Paraiiieter estirnates for the Loam-Clay water release CU rve function...... 46
T'ible 2.9. Paranieter estiniates for the Loani-Sand water release curve function...... 47
Table 2.10. Parameter estiniates for the Sand soil resistance curve function...... 48
Table 2.1 7. Parameter estimates for the Clay soil resistance curve function- ...... 50
Table 2-12 Paraiiieter estimates for the Loani-Clay soil resistince curve function...... 51
Table 2.13. Paranieter estiiiiates for the Loaiii-Sand soil resistance curve function...... 52 Table 3.1. Sumrnary of soil properties for dl plots in each si te (0-30cni depth)...... 60
Table 3.2. Results of regression analyses between yield (+N> and nieasured seasonai average water contents @seas)- ...... 61
Table 3.3. Statistical data for LLWR, FU,,,, and final yields (+N treatments, 0-30cm depth) ...... 62
Table 3.4. Results of regression analyses between y ield (tN)data and the LLWR, Fit,,,,...... 63
Tcible 4.1. Suiii~ii~ir\~of soil properties for al1 plots on eack site (0-30cm dep th)...... 88
Table 4.2. Statistical data for average e,., PEWWs and final yield data for al1 plots...... ~...... - 89
Table 4.3. Resul ts of regression analyses between yield (+N) and ~Iveragenieasured seasonal water contents (Ls)-...... 90
*l'cible3.1. Resul ts ot regression cinctfvses behveen yield (+NI and average uieüsured seasonal water contents (PEW,,,)...... -91
Table 4.5. Resul ts of regression analyses between yield (+N) and organic carbon (OC) ...... 97
Table 5.1. AIGOVA tables of location and fertilizer
effects for each site...... ,...... -115-117 l' Table 5.3. Results of regression analysis between yield (ON) and average plant extractable water during the growing season (PEWms) for each site...... 128 *l'.i blr 5.3. Rrsultt, ol' 1-egressioti ciiicilysisbetween y ield (ON ) .i iid u rgcinic c Figure 2.1. Site locations in southern Ontario...... 10 Figure 2.2 Cornparison of da Silva and Kay (1997) predicted vs. measured values of volumetric water content across a range in matric potential(-0.001 to -1.5 ma)...... 16 Figure 2.3. Soi1 textural classes and textural dishi bution of soi1 cores...... 19 Figure 2.4. Cornparison of T3 pred icted vs. rneasured values of volumetric water content across a range in mahic potential (-0.001 to -1.5 MPa) ...... 22 Figure 2.5. T3, DS1 and DESORPMOD prediction of water reIease curve data of independent data set...... 23 Figure 2.6. Plots of DS1 and T3 predicted values vs. measured values for the critical iiiatric potentials -0.01 MPa (Field Capacitv) and -1 -5 MPa (Pem~anentWilting Point)...... 24 Figure 2.7. Four examples of plots of T3 predicted and measured wa ter release curves...... 25 Figure 2.8. Cornparison of da Silva and Kay (1997) SRC predicted vs. ineasured values for the first data set...... 27 Figure 2.9. Coniparison of 84 predicted vs. measured values of soi1 resistance for the first data set...... 30 Figure 2.10. Coinparison of T7 (linear ip terni) predicted vs. measured values for the first data set...... 31 Figure 2.11. Co~nparisonof T7 (with y=)predicted vs. measured values for the first data set...... 32 Fi pu re 2.1 2 Coni parison of 84 predicted vs. iiieasured values of independent data set (second data set)...... 34 Figure 2.13. Coinparison of T7 predicted vs. rneasured values of independent data set (second data set) ...... 35 Figure.2.14.Comparison of TS predicted vs. measured values of independent data set...... 38 Figure 2.15. Comparison of predicted 0 values using the T8-iterative method vs. measured 0 values for second data set (164 data points) ...... -...... -.. . . 39 Figure 2.16. Coniparison of T3(Sand) predicted vs. measured values of voiumetric water content (162 data points) ...... 44 Figure 2.17. Comparison of T3(Clay) predicted vs. measured values of volumebic water content (1306 data points)...... 45 Figure 2.1 8. Coin piii-ison of T3(Loaiii-Clav) predicted vs. nieasured values of voluinebic water content (1301 data points).. ... 46 Figure 2.19. Coniparison of T3(Loam-Sand) predicted vs. measured values of volumehic water content (645 data points)...... 47 Figure 2.20. Corn parison of T7(Sand) predicted vs. nieasured values of soil resistance (32 data points- first data set)...... 49 Fiçu re 2.21. Coiii parison of TS(C1iiy) predicted vs. measured vdl ues of soil resis tance (196 data points- first data set)...... 50 Figure 2.22. Conparison of T7(Loani-Clay) predicted vs. measured values of soil resistance(74 data points- first data set). .. . . -51 Figure 2.23. Comparison of T7(Loam-Sand) predicted vs. measured values of soil resistance (142 data points- first data set). ... 52 Figure 3.1. Map of sites in southern Ontario ...... 56 Figure 3.2a,b. Plot of the Elora (no tiil) 1999 yield data relationship with the LLWR and Fuw,...... 64 Figure 3.3. Plot of Canagra North (conventional till) yield data rela tionship with the LLWR...... - .. - .. . -...... -. 65 Figure 3.4 a,b. Pred ictioii of wüter contents by the TS and DÇ2 SRC furictions vs. measured values for an indepeiiilei~t data set (-1 64 data points)...... 67 Figure3.5. Plot of vield (+N) vs. the frquency of water contents falling below the permanent wilting point during the growing season (Fpwp) at the Elora (conv. till) 1999 site ...... 68 Figure 3.6 a,b,c. T3, DESORPMOD predictions relative to each other using da Silva and Kay (1997) data...... 69 Figure 3.7. Plot of difference values (minimum recorded TDR values during the growing season - core measured PWP) across al1 1998 sites...... y0 Figure 3.8 a, b. Coni parison of ni inim um recorded soii water vctlues with T3 and DSl PWP predictions ...... --71 Figure 3.9. Plot of yield and the niinîmum recorded water content minus the DS1 predicted PWP, across landscape positions (CS-Canagra site)...... 72 Figure 3.10. Plot of volumetric water content values illecisui-ed bv TDR vs. voluiiietric water content convertrd trotii grciviiiietric sani ples...... -...-• -74 Figure 3.ll. Exaitiple of n predicterl water release curve froiii a clay soi1...... 75 Figure 4.1. Conceptual mode1 describing plant health as a function of soi1 water ...... 81 Figure 4.2. Map of sites in sou thern Ontario...... 84 Figure 4.3. Esciinple of a site with little yield variation (Deiivs site)...... 92 Figure 4.4. Examples of nonlinear behaviour between y ield and PEW,.,...... -...... 93 Figure 4.5af b. Nega tive correlations found behveen yields and soi1 water measures (Podolinski site)...... --94 Figure 4.64 b. Di tfereii t correlii tiotis between yield and rrlat ive cotii pcictioii: Elora no till 1999 (a), Cç-Canagra (b)...... 95 Figure 4.7. Nonlinear beliaviour of yield vs. OC (McCracken site)...... 96 Figure 4.8. Plots of yield with PEW,. and OC. for the Cç-Canagra site...... 98 Figure 4.9. Exampie of the relationship between PEW,. and OC (Cameron site) ...... 99 Figure 4.10. Behaviour of yield. OC and soi1 water contents on the Podolinski site...... -100 Figure 4.11. Conceptual mode1 describing yields as a function of plant extractable water ...... 102 Figure 4.12 Exarnple of the temporal stability of extractable water across spatial patterns (McCracken site) ...... *....-...... -...-103 Figure 5.l. Map of sites in southern Ontario ...... 109 Figu re 5.2. Exauip les of differeiitial location effects on yields: (a) CC-Cnnagra no till 1998. @) Elora conv. till1999 ...... 112 Figure 5.3. CC-Canagra (no till) 1998 site. Evident OC effect upon yield (+N and ON) but no statistically signifiant effect of +N treatment ...... Il3 Figure 5.4. Denys site . No evident OC effect upon yields but St,itisticiiIIy signifie-ant N fertilizer effect ...... 114 Figure 5.5. Yield +N and ON across a range in OC (McCracken site)...... 118 Figure 5.6. Yield +N and ON across a range in PEW.. (McCracken site)...... -119 Figure 5.7. Yield +N and ON across a range of OC (Cameron site) ...... 120 Figure 5.8. Yield +N aiid ON dcross à range ot PEW .,.. (Caiueron site)...... 120 Figure 5.9. Yield +N and ON across a range of OC (Podolinski site) ...... 122 Figure 5.10. Plot of yields in the ON treatment and the frequency of seasonal water contents measured above the 10%air-filled porosity limit (Podolinski site)...... 122 LIST OF ABB@VIXT"TONS ANOVA = analysis of variance AWC = Available water holding capacity Bd = Buik density 84, B5 = Soil resistance pedo tram fer function forms derived by Boucher (1990) COLE = Coeffiaent of Linear Extensibility DS1= Water release curve pedotransfer function derived by da Silva and Kay (1997) DS2 = Soi1 resistance cuve pedotransfer hction derived by da Silva and Kay (1997) FC = FieId capacity Fii,. = Frequencj. of seasonal water contents fnlling outside the LLWR ùuring the srowing sectson FPq= Frequency of seasonal water contents falling below the permanent wilting point during the growing season LLWR = Least Limituig Water Range N LW II = Non-Lirniting Water Range OC = Organic carbon PEW,,, = average soîi water content during the growing season measured above 00, PTF = Pedotransfer Function PWP = Permanent wiltirig point RMSE = Root Mean Squared Errors RC = Relative compaction SRC = Soii resistance curve SSE = Sun-i of Squarecl Errors TDf? = Tinie-Do niai11 Reflec tome try Tl-TS = Pedotransfer functions a ttenipted in this study W RC = W a ter release curve 9 = volumetric water content e,, = average soil water content dwing the growing season 90,= lower limit of water content at which photosynthesis ceased (Kay et al. 1999) \y = matric potential CHAPTER 1: INTRODUCTION 1.1 BACKGROUND Agricultural fields Vary considerably in their soil properties, landscape features, and management histones. As a result, this variability has been showri to contribute to variation in yield. Colvin et al. (1996) described the yield patterns for corn and soybeans in rotation after six consecutive years within a single field. They found that certain locations wïthin the field had consistently high, consistentIy low, or erratic yields when compared to whole field averages. The variation in yield and in many soil properties can be measured with current technology, but the roo t causes of this spatial variability are yet unexplained. The broad objective of this project was to determine the degree in which variation in yield and yield responçe to fertilizer nitrogen (N) are explained by variation in soil structure and water content. If the effects of soil structure and water content on yieId and yield response to nutrients can be found to be significant, then appropriate methods can be developed to nia9 them and develop corresponding management plans. It is assutned that the iniportance of soil structure to yield is related to the soil's ability to provide oxygen, water and support the growth of roots. Carnbardella et aI. (1994) found that aggregate size distribution contributed significantly to yield variability in seven out of seven years, and bulk density, soil moisture, and soil texture in 4 out of 7 years. It was tho ugh t tha t aggrega te size distributions in tegrated the effect of soil characteristics such as texture, minera logy, organic ma tter content, % pore space, soil matric potential, and surface seal formation. These soil properties deal with the direct and indirect effects of structure on soil-water relations and plant available water, which can in tuni affect yield. To quantify soil structure we wiii attempt to use the parameter Non-Limiting Water Ra nge (NLW R), in troduced by Letey (1985), later renanied Least Limiting Watex Range (LLW R). The term Least Limi ting Water Range is defined as the range in soil water content after rapid drainage has ceased within which Mtations to plant growth associated with water potential, aeration and mechanical resistance to root penetration are minimal (da Silva and Kay, 1997). The LLWR is a ranse, defined by an upper limit and a lower limit, The upper Limit value is chosen ds the lower vnlue of water content in which aeration to the roots becomes liniiting, or when rapid drainage ceases. Aeration was concluded to be limituig at an air- filled porosity of 0.1 cm3/cm~Grableand Siemer, 1968), and rapid drainage was concluded to cease at field capacity (FC) at a water potential of -0.01 MPa (Haise et al. 1955). The lower liriiit values were chosen as the greater value of the water content below which water cannot be extracted by plants (perri-ii-inentwilting point or -1.5 MPa) found by Richards and Weaver (1944), or the wa ter con tent at which mechanical impedance restrïcts root growth. Cone penetrometer resistance is conunoniy used to simulate the impedance encountered by plant roots. Young et al. (1997) found that mechanical impedance of root g-rowth directly affected plant growth, and based on studies done by Taylor et al., (1966)and Greacen (IYri6), a cone resistance of 2 MPa was used as the upper limit of penetration pressure exerteci by the roots of iiiost field crops. Fron-i this, the other crîterion for the lower LLWR lir~iitwas based on the water content in which the soil's penetration resistance exceeds 2MPa. 1 t is hy pothesized that the LLWR can be used as a measure of the soirs ability to provide wa ter, air nncl support. ln essence it is hypothesized that the LLWR cmbe used as a nieasure of the soil's ability to provide water, air and a favorable environment for root development and as such, the magnitude of the LLWR will be positively correlated with yields. It is further hypothesized that crop growth will. be negatively correlated to the frequency in which seasonal water contents faU outside the LLWR (Fum)- Here, it is reasoned that as the soil dnes during the growing season, the nurnber of seasonal water contents measured below the lower liniits wiIl increase and yields will be negatively affected- This reasoning is aIso applicable to seasonal water contents measured above the upper limits. Seasonal water contents risuig above the upper Limits v~ouldinduce aeration problems and thus also negatively affect yields. These hypotheses are supporteci by work done by da Silva and Kay (1997) where they used bo th the LLW R and Fii*, (in the O-20cm depth) to assess shoot growth of corn. They found tha t shoot growth was indeed positively correlated with the magnitude of the LLWR and negatively correlated with Fuw,- The effects of the LLWR and Fuwr upon yields however, are unknown. Also, within the scope of this project, soii spatial variability wiU cover a large range of soi[ propertws- Detern~inuxthe wa ter release curve (W RC) and the soil resistance curve (SRC) over this range will be time consurning and expensive. Considering that both the W RC and SRC are affected by soi1 physical properties such as texture, organic carbon (OC) and b ulk density, i t sho ulrl be possible to determine inathematical relationships to predict thé curves. Bounia and van Lanen (7987) introduced the terni pedotransfer functions (PTFs) ~isIII~ themd ticdl expressions thd t reldte ciiffersnt characteristics and properties with one ai10 ther, Le., PTFs could be used in translating data that we cmeasily determine (bulk density, texture, OC) into data we require, such as the WRC and SRC. Da Silva and Kay (1997) developed several PTFs, one of which described the WRC and another describing the SRC, both from various soil properties withïn a single field in southem Ontario. It is hoped that these PTFs can be used to predict the WRC and SRC for the range of soils in this project and in turn predict the spatial and temporal variabiliv of critical water contents and soit properties that atfect plant growth. The broad objective of this study was to detennine the degree in which variation in yield and yield response to fertilizer N are explained by variation in soil structure and water content. Specificdy, the objectives were to: (a) assess the ability of the pedotransfer functions deterrnined by da Silva and Kay (1997) in predicting the water release and soil rrslstdnce properties for d rnngr of soils within southern Ontario and to develop new pedotransfer functions for the water release and soil resistance curves if the da Siiva and Kay (1997) functions were found to be inadequate, and (b) determine the degree in which the LLWR and seasonal water content data in the form of Fuw, can explain the variation in yield and y ield response of corn (Zeamays) to fertilizer. The study was focused on corn crops from sites across southern Ontario, conducted over the two field seasons of 1998 and 1 +M. 5011 struc-tLI re ~11iCfwn ter conteil t were deternùned in the top 30cm of the prome. 1.3 FORMAT OF TH ESlS This thesis is written in the format of 4 distinct units. Chapters 2-5 each contain seprate introductions, niethods, results, references and appendices. Consequently some overlap may exist between chapters. 1.4 REFERENCES Bouma, J., and H.A.J. van Lanen. 1987. Transfer functions and threshold values from soil characteris tics to land qualities. Pp. 106-111. In Quantified land evaluation, Proc. Worksh. lSSS/SSSA, Washington, DC, ITC Publ., Enshede, the Netherlands- Cambardelia, C. A., T.B. Moorman, J.M. Novak, T-B.Park, D.L. Karlen, R.F. Ruco, and A.E. Konopka. 1994. Field-scale variability of soil properties in central Iowa soils. Soi1 Sci. Soc- AM- J. 58:1501-1511 Coivin, T.S., D.B. Jaynes, and D.L. Karlen, 1996. Six-year Yield varïability in central Iowa. (in review, TSAE) da Silva, A. P. and Kay, 6. 0. 1997- Estirnating the least Limiting water range of soils from properties nnd nianagenient. Soil Sci, Soc. of Am. 1. 61(3):877-883. Crable, A.R., Siemer, E.G. 1968. Effects of bulk density, aggregate size, and soil water suction on oxygen diffusion, redox potential and elongation of corn roots. Soil Sci. Soc. Am. Proc. 32:180-186. Creacen, E.L. 1986. Root responsr to soil mechanical properties. Trans. 13u1Congress intem. Soc. Soil Sci., Hciiiibcr rg, Gerniany. 5:20-47 Haise, H.R. Haas, H.J. ,Jensen, L.R. 7955. Soil moisture studies of some Great Plain soils: II. Field capacity as related to 1/3-atniosphere percentage and "minimum point" as related to 15 and 26- atniosphere percentages. Soil Sci. Soc. Am. Proc. 34:20-25. Lete!:, J. 1985. Relatioiiship between soil physical properties and crop productions. Adv. Soil Sci. 1 277-294. Richards, L.A., Weaver, L.R. 1944. Fïfteen atmosphere percentage as related to the permanent wilting point. Soil Sci. 56:331-339. Taylor, 'H.M- Roberson, G.M., Parker, Jr.J.J.1966. Soil strength-root penetration relations for medium to coarse textured soi1 materials. Soil Scî- 10218-22. Young, LM., Montagu, K,, Conroy, J., Bengough, A-G.1997. Mechanical impedance of root growth directly red uces lea F elonga tion rates of cereals. New Phytol. 135: 613-619. CHAPTER 2: USING PEDOTRANSFER FUNCIIONS TO PREDICT THE WATER RELEASE CURVE AND THE SOIL RESISTANCE CURVE INTRODUCTION Agricultural fields Vary considerably in the5 soii properties, landscape features, and management histories. As a result, this variability has been shown to infiuence yieid. Cambardella et al. (1994) found that aggregate size distribution contri'buted sigruficantly to yield varïability in seven out of seven years, and buk density, soil moisture, and soil texture in 4 out of 7 years. It was thought that aggregate size distributions integrated the effect of so il characteris tics such ns texture, niineralogy, organic matter content, % pore space, soi1 matric potential, and surface seal formation. The impact of soil structure on yield is related to the soil's abiiity to support the growth of root.and to provide oxygen and water. The broad-based purpose of this project is to determine the effect of soi1 structure and water content on yield and yield response to fertilizer N. To deterniine the relative effects of soil structure and seasonal water content on yield variation, it is critical to know how matric potential and penetration resistance varies with soil water content Water content changes with matric potential, and the water release cwe (W RC) is a critical relationship that can dehethings such as pIant available water, the cessation of rapid drainage (Field Capacity, FC) and the point at which water is held too tightly by the soi1 matrix for plants to use (Permanent Wilting Point, PWP). Soi1 penetration resistance changes with water content, a relation called the soil resistance cuve (SRC). Thiç relationship becomes critical for plant growth when soil water content becomes so low that soil strength or mechanical irnpedance restricts root growth. Cone penetrometer resistance is commonly used to simulate the irnpedance encountered by plant roots. Young et al. (1997) found that mechanical inlpedance of roots shows direct negative effects on leaf growth rates, even in non-liniiting wa ter and nutrien t reginles. Also, in studies done by Taylor et al. (1966) and Creacen (19S6), a cone resis tance of 2 MPa was found as the upper lunit of penetration pressure exerted by the roots of most field crops- Therefore, howledge of the SRC can provide us with a tool to detennine points of critical soi1 water within a growing season in which mechanical inipedance wiLI effect plant growth. Soil properties are spatialiy variable. Detennining the spatial variability of the WRC and SRC will be time consuming and expensive. Considering that both the WRC and SRC are affected by soi1 physical properties such as texture, orgariic carbon (OC) and bulk density, it should be possible to detennine mathematical relationships to predict the cwes. Bouma and van Lanen (1987) introduced the tenn pedotransfer furictions (PTFs)as niathenia tical expressions tha t relate clifferent characteristics and properties with one dnothel-, i.e., PTFs couic- be used in translating data that we can easily detennine @L& density, texture, OC) into data we require, such as the WRC and SRC. Databases of soi1 hydrauiic properties have been developed into PTFs in the USA (Leij et al., 1996), Europe (Wosten et al. 1995), and Australia (Minasny et al., 1999), but the utility of these hctioms is most likely restricteci to the soils from which they were developed. If we are to use PTFs b\:~th in this pi-ojrct, the functions inust be developed to encompass the variable soil pro perties of the local region. Da Silva and Kay (1997) developed several PTFs, one of which described the WRC and another describing the SRC, both from various soil properties within a single field in southern Ontario. The WRC PTF was of the fom: 8 = aq~" where 8 = volumetric wa ter content. y1 = matric potential, a and b are functions of % clay, bulk density md OC. By linearizing this equation and using muiti-linear regression techniques, their mode1 accounted for 94%of the variation in inû. The SRC MFwas of the form: SR = cûdBde where Bd is bulk density, c and dare functions of % clay, bulk density and OC and e is a fimction of % clay and OC- Lineariurig this equation and using multi-linear regression, their i-iio~ilelaccounted for 86% of the variability in Ln(SR). The objectives of this chapter were: (i) to assess the ability of the pedotransfer functions determined by da Silva and Kay (1997) in predicting the water rele~seand soil resistance curves for a range of soils within southem Ontario and (ii) to deveiop new pedotransfer functions for the water release and soil resistmce curves if the da Silva and Kny (1997) functions were found to bé hadequate, 2.2 MATERIAL AND METHODS This study was conducted upon 6 farms during the 1998 growing season and 4 farms during the 1999 growing season. AU farm sites were iocated between Thamesville and Beeton, Ontario, Canada (Figure 2.1). Ail farms were planted to corn (Zea mays) in the season of sampling. Tillage on al1 farms was either conventional tïll or zero-till management Figure 2.1. Site locations in southern Ontario. Plot locations ai each site were selected on the basis of landscape position. It was expected that the different landscape positions would encompass the range in yields, soi1 properties and water content on a given site. The experiniental design of this project was a factorial experiment using randomized complete block design with several repiications, each with several plots dividecl by landscape position and 2 treatments: 150kg/ha N fertilization and no N fertilization. Eight of the farms were characterized by establishing 24 - plots: 4 replicates, each with the 2 N treatments, and 3 landscape positions: uppex dope, mid-slope and toe-dope positions. The remainirig sites were located at the Elora Research Station where each site was characterized by 30 plots: 3 replicates with 2 N treatments and 5 landscape positions. For aii farms, plots were approximately Sm long and 6 rows wide. At the coinpletion O t each growing season, prior to harvest, undisturbed cores (5cm diameter x 2.5cm height) were taken at each plot Four cores were taken at 5-7.5cm depth and another four cores were taken at 20-22.5cm depth. Ln all, 2076 cores were collected. Each core was wrapped in cellophane and stored at 4OC unid used for experimentation. As part of nno tt~erstuciy, 272 cores (sanie dimensions) were taken from various id rtns in 1997 Ln order to iiicrease the range in soi1 properties being examined. These cores were taken at 5-7.5~111, 15-17.5cm and 25-27.5cm depths and were also used for the WRC and SRC analyses. The W RC was deterrnined using the methodology of Topp et al. (1993). Overd, the 272 cores ta ken in 1997 and 165 of the cores taken in 1998 (chosen to encompass much of the vnria tion across the tii rm) were used to determine the W K. Samples were saturated and equfibrated on pressure pIates at 9 potentials (\y = -0.001, -0.002, -0.004, -0.006, -0.01,-0.0333, -0-1, -0.4, and -1.5 MPa). The SRC was deterniined using similar methodology to da Silva and Kay (1997). Rrsis tmce to peiietrd tion was deterniined on 777 cores, 495 of the cores taken in 1998 and 222 of' the 272 cores taken in 1997. Of the 495 cores taken in 1998,165 of these cores were the same cores that underwent the water release curve analysis. These 165 cores, when taken out of the pressure chambers at -1.5 MPa, were weighed and then used for resistance measurement. The remaining 552 cores were saturated and brought to different potentials (y = 4-001,-0-003, -0.006,-0.01, 4.0333, and -0.1) in pressure chambers to achieve variable water contents for the measureinen t of soil resistance. The soil resistance to penetration was measured using an ELE Digital Tritest 50. Instrument control and data collection was achieved using Sciemetric 200 interfaced with a computer. Soi1 resistance was m.eaçured in each core at penetration of 2mm/ min. using a cone penetrometer with a 30' cone angle and - a 4mm basal diameter. Only one penetration was performed per core, each done in the center of the core. Through the computer interface, approximately 450 readings were taken per penetration. The average and the maximum penetration resistance found between the 0.4~~1and 2,Ocni depth of each core was recorded. After both the WRC and SRC data were recorded, all cores were oven-dried at 100°C and bulk density values determined- The soii from each core was then split into 2 parts; one pdrt was sieved (2iiiiii) nnd used for pdrticie-size analysis; the other was ground anci used toi- OC malysis. Pa rtide size analysis was done using the hydrometer method and calibrated with the pipette method (Sheldrick and Wang, 1993). Organic carbon analysis was done using the LEC0 SC 444. Data Analysis The WRC and SRC PTFs used by da Siiva and Kay (1997) are nonlinear functions, iînearized to statisticaiiy fit the data and because of this, their results show prediction of Ine or LnSR Transforiiiation froin the log form back to its original form (8 or SR) introduces erro r, therefore eva luation of the W RC and SRC PTFs were evaluated in their original nonlinear forms to gauge their true error in prediction. Nonhear analysis cannot use conventionai statistical tests such as the coefficient of determination (r2) so anaiysis was based upon cornparison of the Sum of Squared Error (SSE): SSE = C(8i - €Ipi)' for i = I.....N where Bi and 8pi are the ith rneasured and predicted values of 0, respectively, and N is the nuniber of data points. The Root Mean Square Error (RMSE)is: where p is the number of parameters in the model. The RMçE is an evaluation of the mean of the prediction error of a model- Regressions of predicted vs. measured values were also andlyzed. This regression gave a sense of how well the model predicts and where prediction s tra yed from niersurrd da ta. Coefficient of deterniination (rz) for this regression was looked a t but was no t considered an accura te assessrnent of the prediction for the model. New PTFs were deterrnined using multiple linear regression and non-hear regression techniques. Validation of the new models were performed on independent sets of da LI ond judgrd bdssd on SSE, RMSE and the same 1:l regression analysis of predicted VS. nieasu rd values. 2.3 RESULT5 AND DECUSSION Water Release Curve (WRC) Water release, texture, OC and bulk density (Bd) data were generated for the 165 cores taken in 1998 and the 272 cores taken in 2997. Of the 437 cores, several cores were rendered unusable because of pore modification due to Worms, during experimentation. Also, some WRC data was rendered unusable due to mïssing values. Overall, 3412 data points were generated fiom 385 cores. Textural analysis of the cores showed that our data ranged From O -60.3% clay content and 3.2- 928% sand content Organic carbon and Bd ranged fron10.25-5.88% md 1.05- 1.79 g/cm3, respectively. A surnmary of aU soil properties, by site, is shown in Table 2.1. Table 2.1. Surnmas, of soi1 propertïes for ail plots in each site (0-30andepth). Farm: BuJk Density: Organic Carbon: % Sand % Qay EC98: Elora 1998 Average: (conv. till) St. Dev.: Minimum: Mctxhum: EYti: Elom 19% A vcmcrge: (no Lili) SL. Dev-: Müumum: Maximum: EC99: Elora 1999 Average: (conv. till) St. Dev.: Ivlinimum: Maximum: E99: Elora 1999 Average: (no till) St. Dev.: Minimuni: hlldxiiii u~ii: A vwiij;c*: 51. Dev.: Minimum: Maximum: Podolinski Average: (conv. till) St. Dev.: lvlinhum: Maximum: A vcral;c: SL.Dc-v.: h4 i rii ni LI ni : Mixmi uni: A vcrci2;e: SL. Dev.: Minimum: Maximum: CC: Canagra Average: Sou th St. Dev.: (no till) Minimum: Maximum: A vcv-i !;c: SL. Dcav.: i rii III LI 111 : Mdxiuium: A vcrcige: St. Dev.: Minimum: Maximum: Newcombe Average: (no till) St. Dev.: Miriini uni: The developed by da Silva a&dKay (1997) to predict the WRC (now referred to as DSl), was used in conjunction with data on BD, clay and OC contents to predict values of volumetric water content (8) which were then compared with measured values for the 385 curves. Analysis of prediction for DS1 resulted in a SE= 19.65 and a RMSE = 0.076 (cmS/cm3). The regression of predîcted vs. measured values (Figure 22) resulted in a r2 = 0.72 but also an intercept of -0.06 (cm3/cm3) and a slope of 1.07, where the intercept was significantly different from zero and the dope was sigmficantly different fiom 1. Residuals were not randomiy distributeci about the 1:1 lîne indicating that the functional fom of DS1 niay not be appropriate to describe our data. 0.8 4 - O I SSE = 19.66 0.7 Ï RMSE = 0.076 -- O 0.2 0.4 0.6 0.8 Measured water contents (cm3lcm3) I I Figure 2.2 Coniparison of water contents predicted by the da Silva and Kay (1997) M'F with IlItldSU:red voluiiietric wa ter contents across a range in matric potential (-0.001 to -1.5 MPa). While DSl can predict approxin-iately 70% of the variability in the WRC data, for Our pu rposes more accura te prediction was needed and therefore attempts were made to define a new PTF. The different models attempted in definïng the new function are shown in Table 2.2. The new attempts included a refitting of the parameters in DS1 to Our database, as well as attempts to fit our data to the more common WRC fom, the Van Genuchtm equation, and finally another S-curve Like function, a logistic function. Table 2-2- Model formç fitted to the measured water release data (385 cores with 3412 data points overall). Mode1 Name: Equationr Tl :refitted da Siiva and Kay (1997) 0 = a*$~ T4: Simplifieci Van Genuchten TS: Logistic Where t) = Vol, wdtcr ~-ontciit(init/~m-l), = matric potcntid (MPa), and a,b,X; &Br,aand nare C-urvefitting parameters. Equation Tl, the refitting of the DS1 parameters to our database, was of the form: 6 = a@ and was Linearized to w hrrr 8 = Vol. wdter content (ciii'/ctii-'), III = nia tric potential (MPa). The resulting Tl MF (data nof shown) accounted for 81.7% of the variability in inû. Prediction of 8 (the nonlinear fom) reçulted in a SSE = 6.58 and a RMSE = 0.044 (cm3/cm3). Regression of the predicted with measured values of 8 resulted in a r2 = 0.814, an intercept of 0.03 and a slope of 0.94, whrre the in trrcrpt was sigiiifican tly different than zero and the slope was significantly ditteren t than 1. 1 t ici11 be seen thàt Tl shows an irnprove~nenton the DS1 PTF. Two tunstions were also tested to determine if the more traditional s-cuve shape of the WRC could be sirnulated. They were: the Van Genuchten equation (T2), 8 = 8s - 8r +8r (1 + ((a*l I)n)(1-l/n)) where 8s = €3 ai saturation, 8r = the residual8, a = the air-entry value and n = the curve shaping parameter, and a logistic function (T5), where a corresponds to û a t saturation, and band k are cuve shaping parameters. Both T2 and TS were fitted to aU water retention data using nonlinear regression (Gauss-Newton) procedures. This method attempts to rninimize the sum of squared errors (SE)using an itera tive method when given the functional form and starting values for all coefkients within the functiori- Results for nonlinear regression of water release data across all cores for the T2 and T5 functional forms resulted ut little or no convergence of the coefficients within the equation. It was hypothesized that the water release data may contain ranges of soil properties (texture, OC, Bd) that were too wide for a single equation of this complexity to rncompass al1 the variation found within the water release curves. To decrease some of the variability, the water release da ta were divided into 4 classes based upon texture. A study bv Tietje and Tap kenhbrichs (1993) suggested that establishment of separate PTFs for different textural classes can yield good results. Also, Rengasamy et al. (1984) suggested that for soils with c 30% clay content, behaviour of soil physical properties changed with %clay con tent but in soil with 30% clay content or greater, change in soil physical properties drpeiided on the types of clay present and not clay content alone. Therefore, four textural classes were detennined: Clays (>30%clay), Sands (>70% sand), Loam-Clays (<30% clay and ~35%sand) and Loani-Sands (<30% clay and 70%>Sand>35%). The 4 soil textural classes are shown in Figure 2-3. O 20 40 60 80 100 Sand Content Figure 2.3. Soi1 textural classes and texturai distribution of soi1 cores. Another problem encountered in the nonlinear regression process involved the use of 0sor a, the voIumetric water content at saturation. Ln many instances at the wet end of the W RC, measured volurnetric water content. were found to be greater than the porosity calculated from the Bd after oven drying. Measurement of Bd, experirnental error and the in fluence of particle densi ties were analyzed but it was deterrnined that the most Likely explanation for this resuIt was shrinking and swelling. If shruiking and swelling were occurring in our soils, the statistical determination of es within a WRC MFwould be difficdt, therefore any determination of a PTF must account for swehg. A common d pproach to accoun t for swelling in volves the use of the Coefficient of Linear Extensibility (COLE). Throutgh the use of COLE a new Bd, porosity or water content accounting for swellu-ig can be calculateci. The use of COLE however requires the standardization of the COLE parameter for the local area with its unique clay types and swelling properties. Rudimentary calcula tion of COLE can be niade by simply using % clay content and organic nutter content but i t was determined that, within our data set, swehgwas not consistent with clay content or organic matter. Ln general it was found that approximately 8%,18%, 34% and 26% of the data points for the Sand, Loam-Sand, Loanx-Clay and Clay textural classes respectively, showed evidence of swelling. Whai degree of swehg (expressed as the volunietrïc water content at 0.001 MPa suction minus the porosity of the core calculated from the oven dry Bd) was regressed against % clay content or %organiccarbon no significant relationship was found. While there may be a relationship between X clay and the frequency of swelling occurrence, the large amount of variation in the degree of swelling made the regression with properties insignificant. Due to the large variation inherent in the swelling occurrences within our data, it was concluded that the use of COLE wouid not in~proveour ability to define a WRC MF. Therefore, to account for swelling within our data, only data points that exhibited 8 values greater than the measured oven-dry porosity were àdjustd. For the data points in question it was assumed that the volume of water rneasured at that potential was equivalent to the volume of soil pores: Vol, = (1 - (M,/Vol~~i)/2.65)*Voltoti1 where Vol, = measured volume of water (cm3), M, = measured mass.of solids (g), and Voll,,.,~ = calculated volume of swelleti buksoil. W ith rearrangement this equation becomes: Volt,t,i = Vol, + MJ2.65 Therefore for al1 data points showing the presence of swelling, variables such as volumetric water content, buk density and porosity were recalculated usirig Voibbi. For those data points that did not exhibit evidence of swehg. calcdation of volumetric water content and 66 and porosity were baseci on the volume of the cores. Therefore, the 3 variables vu lu nie tric wd ter content, Bd and porosity (por)are redefïned Bd2and porz in which aU three variables encompass swelling and non-swehg data points for a soil. Nonhear regression of T2 and T5 was performed for each texhval class with water release data using 0, Bd and por, as well as their counterparts 0%Bdz and porz. Using the testural classes dnd the swelling paranieters however, did not irnprove ouability to reach convergence for our WRC data- The T2 function was thought to be too complex for the regression analysis and perhaps the simplified versions, T3 and T4, might yield better results. ln contrast, the T5 function, the logistic function, was thought to be tao simple and thus unable to adapt to encompass the variability of the WRC data. Nonlinear regression of the simplified Van Genuchten equations (T3 and T4) were performed for each textural class with water release data using 8, Bdand por, as well as their counterparts el, Bd2 and porz- Regreçsion results for all functions (Tl - T5) are shown in Tdble 2-3. Function 7-3 resulted in the best fit (based on smallest SSE and RMSE) using: Where:Bs = por2 Or = (a + b*%clay + c*% 0.C- + d*Bd) a = (e + f*% clay + g* % O.C. + h*Bd) n = (i + j*%clay + k*%O.C.+ 1"Bd) and a.--/are constants. In renioving the (1 - 1 / n) ter111 froni the Van Genuchten equation, T3 became less complex, still retaïned its S-shape forni but lost some of its sensitivity. Mode1 T3 prediction and mode1 parameter estimates for each textural class are shown in Appendix 2.1. When all4 classes of T3 are combined the overall prediction for the 3412 data points resulted in a SSE = 3.56 and n RMSE = 0.032 (cnG/cni~).The regression of T3 predicted vs. measured values (Figure 24) I-~SLItted in rt 1-2 = 0.89, an intercept of 0.04 and a dope of 0.89, where the intercept was sisn ifican tly ciifteren t from zero ancl the slo pe was significantiy different from 1. Despite the significance of the slope and intercept values for the predicted vs. measured regression, the plot indicates that there was no strong, consistent deviation from the 1:l Line at the wet or LI1-y end of the W RC. -0. 4 SSE = 3-56 P! RMSE = 0.032 Measured water contents (crn3/cm3) Figure 2.4. Coniparïson of T3 predicted vs. measured values of volurnetrïc water content across a range in matric potential (-0.001 to -1.5 MPa). - Table 2.3. Results of mode1 fits to measured water release data- Predicted vs, Measured Regesion Data Mode1 Name: Dafaset: SSE: RMSE R2 Çlope Intercept DSI: da Silva and Kay (1997) N = 3412 19.66 0.076 0.74 1.07 -0.06 Tl : moifiiielf Lf~lSilvrl ~tnd N = ,3412 6-38 0.044 0.814 0.94 0-03 Kav (1997) T2 : Van Cenurli~cii N =,Ml2 Fded to converge (4 ilii~~cï;) T3: SimpLifiezI Va N = ,3412 3 -36 Genuchten (4 classes) T4: Simplifieci Van N = 3412 3 -96 Genuchten (4 classes) T5: Logistic N = 3412 Faileci to converge- / I 1 (4 clirsses) 1 I * not sigiuficilntly Liifferent tiian 1.0 (p = 0.05), not si~cantlydifferent than zero (p = 0.05) To determine if the T3 function is truly better than the DSI bction, T3 must be evalua ted using an independen t data set. In the experimental analysis, 330 of the cores taken in 1998 did not undergo the WRC analysis but were saturated and put at various single pressures (-0.001, -0.003, -0.006, -0.0'1, -0.0333 and -0.1 MPa) to be used for soi1 resistance dnalysis. Theso data represent an independent data set of points on the WRC, and were used to test the prediction of DS1, T3 and another commonly used PTF, DESORPMOD (McBx-ide and Mackintosh, 1984). Overall, 101 of the original 330 cores used for this part of the analysis were lost due to worm action and rnissing da ta points. Using the remainirig 229 data points, DS1, T3 and DESORPMOD were used to predict the W RC. Analysis of the independent data set cmbe seen in Figure 2.5. Based upon the plots of predicted vs. measured values and RMSE values, it can be seen that the T3 function predicts the WRC data considerably better than either DST or DESORPMOD. Measured water contents (an31cm3) DE- Redi ction Figure 2.5. T3, DS1 and DESORPMOD prediction of water release curve data of independent data set. Thusfar, it can be seen that the T3 PTF provides the best fit for Our measured data. For the purposes of this study however, it is critical for the &al FTF to accurately predict certain points such as Field Capacity (FC, -0.OlMPa) and the Permanent Wilting Point (PW P. -1.5MPa). This analysis was done upon the original data set of 3412 data points. The independent data set did not encompass pressures of -1.5 MPa and therefore this analysis was precluded. Results of mode1 prediction of DS1 and T3 for -0.01 and -1.5 MPa are shown in Figure 26. Cornparison of DS1 and T3 prediction indicates that T3 prediction considerably decreases the SSE giving the prediction a much tighter fit The plot of T3 predicted vs. measured values of the 385 cores also shows a much better digrunent with the 1:1 lùie. T3: 4-01MPa Redictiai L Figure 2-6. Plots of DS1 and T3 predicted values vs. measured values for the critical matric potentials -0.01 MPa (Field Capacity) and -1.5 MPa (Permanent Wüting Point). Therefore, of the existing models DSI, DESORPMOD, and of those attempted Tl - T5, T3 is detennined the best PTF to predict the WRC of our soils, based upon its prediction of our data as weU as its prediction of the independent data set- Four examples of how the T3 PTFs predict the W RC can be seen in Figure 2-7. Sand (7S%sand. 8%day. 1.72%O.C.. 1.49gkm3) Figure 2.7. Four examples of plots of T3 predicted and measured water release curves. Soi1 Resistance Curve (SRC) Rrsistance to penetra tion was determined on 717 cores, 495 cores taken in 1998 and 222 of the 272 cores taken in 1997. Of the 717 cores used, 232 of the data points were lost due to either worm action, lost data or measurement of penetration resistance was beyond the measuring capacity of the transducer of the Sciemetric 200 apparatus. The measuring capacify of the transducer was approximately 12000 kPa. The remainirig 485 data points were divided into two data sets where the 321 usable cores of the 495 cores taken in 1998 became the first data set and the 164 usable cores of the 222 cores taken Ïn 1997 became the seccnd data set. The first data set wns used to test the da Silva and Kay (1997)ÇRC PTF (now referred to as DS2), and the second data set was reserved for vaLidation purposes in anticipation of generating a new PTF. Textural analysis of the first data set showed that ou data ranged from 0.01-53.0% cIay content and 4.2- 92.8%sand content- Organic carbon and 6ci rd nged fro III 0.25-5.88% and 0.90- 1.74 g/crn3, respectively. The second data set çhowed thcit data 1-dngttci fi-oiii 7.0-60.3% clav content and 3.2- 80% sand content. Orgmic carbon and Bd for the second data set ranged from 0.39-3.3% and 1.18- 207 g/cm3, respectively. To validate the da Silva and Kay (1997) SRC mode1 (DS2), predicted values of SR were compared against measured average SR values of the first data set, Analysis of pred iction for DS2 i-esultecl in a SSE = 9.94 x 1P and a RMSE = 1943.8 kPa. A plot of DS2 pi-edicted vs. iiirasurd values is shown in Figure 2.8. Considering that for the purposes of ttiis s tudy we w ish to determine the volumetric water content at which soil penetration resistance reaches 2000 kPa, a PTF with a RMSE of approxirnately 2000 kPa is cIearly inadequate. 14000 -m ; a I SSE = 9.94E+8 * 12000 ; RMSE = 1943.8 Q> I * N = 321 c. .- 8000 M easured soif resistance (kPa) Figure 2.8. Coinparison of da Silva and Kay (1997) SRC predicted vs. measured values for the first data set To achieve more accurate predictions of SR, atternpts were made to define a new SRC pedotransfer function. Busscher (1990) attempted to define a relationship to describe how soi1 resistance to penetration varied with water content He evaluated several functions, three of which worked particularly well, one of which was of the same form as DS2. To define a new SRC PTF for our data we attempted to redefine the parameters of DÇ2 to fit Our data, as weU as attempting two of Busscher's better functions (B4 and B5). One other functional form was atternpted where soil resistance was descnbed as a function of a zoiiibination of Factors. Hillel (7980) stated that resistance encountered by a metal probe penetra ting the soil encoun ters several processes or effects in combination: the cutting or separaticn of the soil, shear failure, plastic flow, compression, metal to soil. friction and soil to soil friction. While it is virtually impossible to separate each process and quantify it from our single penetration resistance it can be theorized that the resistance to penetration arises fi-oni the Lquici phase and the solid phase. The liquid phase contributes to penetration resistance through etZ~ctivestress (soil particles are held together by the cohesion/adhesion forces of pore water). The effective stress terni has been described by Bishop (1959) as: Effective stress = (fy) where x is related to saturation (O/porosity). Bishop md Blight (1960) however, found that the x tenn was not simply a iinear function of B/porosity but showed evidence of curvatue. The effective stress plays a role in the cohesion forces of both the separation of soil particles (tensile strength) as well as the shear failure of soils. The contribution of the solid phase in penetra tion resis tance can be related to O ther processes such as the cementation of mineral particles by organic matter or clay to clay bonding, as well as the interna1 kiction forces of the probe and soi1 particles. It is theorized that these forces wilI be related to OC, and clay content and thé 6J of the soil. The cohesive forces of organic matter and cIays however, will also be dependont on the soi1 water content. Frictional forces wïil also be affected by soil water content. Therefore it is aIso theorized that these forces wiil be related to water content Overall, the form of the final SR MFattempted WUtake the form: SR = a*8 + b*(8/ porosity)c*yr where a is a function of soil properties and [a*O] represents the contribution of the sohd phase to SR, md b and c are also functions of soi1 properties and ~*(B/porosity)c*yl]will represent the contribution of the liquid phase to SR. Ali equations considered in defining a new SRC PTF are shown in Table 2.4. To furtfttlr enhance the sta tistical process, the database was again divided into soi1 textural cldsses: Sand, Chy, Loani-Sand and Loam Clay (Figure 2.3). Also, the parameters L-onsiciel-ed in clefining the new PTF also included those that account for swelling: 0%Bdz and porz. Table 24- Model forms fitted to measured soii resistance to penetration data (first data set of 321 cores). Model Name: Equation: Tb: refittcd da Silva and Kay (1997) SR = a*Ob*Bdc T7- Combination function SR = a*B + b*(B/por)&y The equa tion T6 was fi tted to the first da ta set using the same nonlinear statistical niethoci usecf in genera ting the W RC PTFs. Nonlînear regression of T6 with the first data set resulted in convergence with the traditional soi1 parameters of texture (%clay, %sand),Bd and OC, but prediction was very poor. Regressions withïn each textural class consistently resulted in RMSEs greater than 1OûûkPa with the Sand class giving the poorest predictions. in ni1 a tteiiip t to red uce the error in predicting SR, a trial was done incorporating matric ptei~tldi (\II) d5 one of the paraiiieters included as a soil properv. introduction of the \y term in to T6 grea tly reduced errors in prediction. The general T6 fom that yielded the best fit was: SR = (a + yj h)'(e(e + f% cLiy + g'0.C- + h*Bd))*(Bd(i+f 0.C)) tviiere n,. ..;are constants anci the presence of some paranieters are dependent on the teltu rd l iidss. 1 II every telturd1 ciass except the Sand class, the y/h tem~considerably reduced the SSE and RMSE. The b constant was consistentiy and sigrufrcantly less than 1and different than zero. The overall prediction of the 4 classes for the 392 data points resulted in a SSE = 1.8 x 108 and a RMSE = 685.8 kPa, a substantial irnprovement over DS2. The regiession of T6 predicted vs. nieasured values resulted in a rz = 0.78, an intercept of 28.1 kPa (not sigi11ticdn tl\: ditferent than zero) and a slope of 0.98 (not sigrüFicantly different than 1). In an objective sense the 1-6 PTF prediction is a significant improvement over the DS2 PTF but the form of the function was based upon parameters that gave the best fit, rather than fmctional relevance. The other two Busscher (1990) models B4 and B5, were dso fitted to the first data set Analysis using mode1 B5 reached no convergence with any of the parameters of texture, Bd of OC- Mode1 B4 however, which containeci a vc term, converged and resulted in a good fit. The B4 fit resulted in a SSE = 1.6 x IOs and a RMSE = W.6kPa. The regression of B4 predicted soi1 resistance values vs- the measured values for aII texturd classes combined (Figure 29), resdted in a rz = 0.81, an intercept of 26.6 kPa (not significantly different than zero) and a dope of 0.99 (not sign ifican tly different than 1).The general form of the B4 PTF wds: SR= (a + b"% Clay + c*% 0.C. + d*B&)*(Bd,(e+ r%cI.y+ g'rO-C))*(@ + Vchy + k'= O-C+ I'B9) where parameters a.../are constants and the presence of some parameters are dependent on the textural class. SSE = 1 6E+8 RMSE = 640.6 N = 321 O 2000 4000 6000 M easured soi1 resistance (kPa) Figure 2.9. Cornparison of 64 predicted vs. nieasured values of soi1 resistance for the first data set. The final function, T/: was the functional form that combined te- related to the Liquid and a solid phase. Of note is that of ail the previous MFs that have resulted in good fits, they have contained a matric potential term as well as having the potential term appear as a nonlinear form vb. The functiond form T7, using only y as a hear tenn, resulted in a SSE = 23 x 1s and a RMSE = 773.9 kPa. The regression of T7 predicted vs. measured values are shown in Figure 2-10. I 10000 (O SSE = 2368 4 8000 RMSE = 773.9 ?? 1 N = 321 O 2000 4000 6000 8000 Measured soi1 resistance (kPaO Figure 2.10. Cornparison of T7 (linear yr term) predicted vs. measured values for the kst data set Aciciition ot LI pu~vel-tel-111 to Iiowrvrr wds the wedliest fi ttirig class for al1 PTF forms attempted in Table 2.4. The new functional forni of T7 with the nonlinear ry terni resulted in a SSE = 1.6 x 108and a RMSE = 660.9 kPa. The regression of the new T7 predicted vs. measured values (Fiwe 2.11) redted in a r' = 0.80, an in tercep t of 334.6 kPa (significantly diffzrent than zero) and a dope of 0.80 (significantly d ifferen t fro m 1).The significantly differen t slope and intercep t values were heavïly uinuenced by the measurements at extremely high resistances. When comparing the two T7 plots of predicted vs. measured values (linear \y vs. nonlirtear y km)however, it can be seen that adding the power terrn to \CI narrows the errors in prediction, especially in the area of lower resistances. The general form of the T7 PTF was: SR = (a+-b"%clay+c*% 0C.+d*Bd2)"82 + (e+f*% clay +g*% 0.C.+h"Bd2)'((8z/ porz)(i+i'%cW+k'%O-'=-+I*W)*(yz) where a.. .x are constants and the presence of some parameters differ between texturd classes. In the Sand and Loam-Sand functions % sand was a more significant parameter than 21~-lci!f- SSE = 1.6E+8 RMSE = 660.9 i N = 321 1 O 2000 4000 6000 8000 Measured soi1 resistance (kPa) Figure 2.11. Coniparison of T7 (with tp) predicted vs. measured values for the first data set. Results froni al1 functional fits are shown in Table 2.5. It cmbe seen that the B4 functional forni, fitteci to the first data set, revealed the lowest errors in prediction and the best fit. Based on SSE the T7 functional form showed simiiar prediction to M. Table 2.5. Results of mode1 fits to meaçured soil resistance to penetration data (first data set), 1 1 Predicted vs- Measured 1 1 Reeression Data - Modcl Name: D;ih scL: 1 SSE: PWîSE: R2 Slope Intercept DS2 di Si1 v* id Ksy (1 997) N = 521 1 9-94x 10" 1943.8 0.299 0.68 479.3 SRC T6 :modifieci da Silva and N = 321 1.8 x 108 685.8 0.784 0.98' 28.1" Kay (1997)SRC B4: Busscher (1990) N = 321 1.6 x 108 640.6 0.813 0.99' 26.6" 1 BS: Busscher (1990) 1 N = 321 Failed to converge. I Tf: Combination functiun N = 321 / 1.6 x 108 660.9 0.799 1 0.80 334.6 I 1 I I I * not sil:tiific.a n~lydiffwimt thn 1 .[) (p = O.CE), " not signih'cantly dilferent than zero (p = 0.05) To determine the best PTF to predict the SRC both the B4 and T7 functions were validated on an independent data set, the second data set consisting of 164 cores taken in 1997. The second data set had similar ranges in soil properties when compared to the first cl4 trt set escep t tlia t the second da ta set's range in % clay and Bd were slightly higher than the first data set. The secon~ldata set rangecl up to 60.3% clay (compared to 53.0%) and a Bd of 2-07g/cm3 (compared to 1.74g/cm3). Validation of the two functions revealed that the T7 hction predicted soil resistance in the independent data set better than the 64 function. VaLidation of 84 prediction resulted in d SSE = 1.02 A 10s dnd d RMSE = 805.9 kPa. Regression of 64 predicted vs. measured vd l ues (Figure 2.12) resu l ted in a rl= 0.595, an intercep t value of 373.2 kPa (significantly differen t than zero) and a dope of 0.88 (sigpficantly different than 1). O 2000 4000 6000 M easured soi1 resistance (kPa) Figure 2.12 Cornparison of B4 predicted vs. measured values of independent data set (second data set). The va iida tion of T7 precliction revealed a better fit thm B4, resulting in a SSE = 6.05 - 1 IOï and d RMSE = 6226 kPa. The regression of T7 predicted vs. measured values for the second data set (Figure 2.13) resulted in a rz = 0.768, an intercept value of 157.0 kPa (significan tly differen t than zero) and a slope of 0.93 (no t significantly different than 1). Regression of the predicted vs. measured values shows that T7 variance in prediction increases at higher soi1 resistances, Overa II, it was judged that the T7 PTF was the best tunction when judged on i ts perforn-iance fron-i the fitted data set and the validation data set- The T7 mode1 parameters for each textural ciass and their significance are shown in Appendix 22. 4 7000 Y SSE = 6.05E7 f 6000 RMSE = 6226 N=1o4 --5 5000 ffl i l M easured soi1 resistance (kPa) Figure 2.13. Cornparison of T7 predicted vs. measured values of independent data set (second data set). If wr are to consider the T7 PTF for the purposes of this study, the T7 function must be used to deternline a volunietric water content at which the soil resistance to penetration reaches a critical value. Unfortunately, the T7 PTF is a function of both 8 and q~: SR = a9+ b*(û/por)c*v adbecause of this, defiriing a critical soil resistance threshold and its correspondirig 8 value will be diiticuIt. In the previous section we have defined a WRC function, T3, of the form: w here 8 is a function of \II- W ith rea rrangement T3 can be made to form: where y, can be expressed as a function of 8. Substitution of T3i into the T7 SRC hction transforins the T7 function to predict SR as a function of only 8. Nonlinear regression of the ti-ans foi-ined T7 function w i th soi1 parameters was again performed but no convergence of the parameters was attained. Part of the problem of redefuwig the parameters in the transformed T7 function was due to the nature of the T3i function. Analysis of T3 showed that 8 cari be predicted with good accuracy by using yl. Intuitively, one would assume the inverse function would also predict well but analysis of T3i showed that prediction of yl as a function of 8, using the exact parameters used in T3, gave very poor results. When considering the nature of the wa ter rslease curve, however, one can see that as one predictç 8 from y~,errors in 111 can cause prediction errors of 0-05 or even 0.10 cm3/cm3 in volumetric wa ter content. In contrast, the inverse function (T3i), when predicting \y from 0, small errors in 8 cm mean order of magnitude changes in predicting \y. Therefore modification of T7 to enhance its utility usùig T3i or other water release functions was deemed unlikely to An alternative to substitu ting T3i into the T7 function was to insert T3 itself to n-iodrSl T7 into a function predicting SR from only y/: where T7 is: SR = a% + b"(8/por)c*y1e 1 cind eacl-i 8 is substituted by 8 = 9s - 8r +Or (1 + (a*yr)n) This new funritional forni will be renamed T8. ln transforming T7 into Tg, the SRC hction is now defined by only one water-related variable, y. Once a critical soil resistance to penetra tion (Le. 2000 Wa) has been defined it should then be simple to use this new function to calculate the \II value açsociated with that soil resistance. With that y/ value we L-~II then use T? tu c-,iIc.uld te the c-oi-1-esponding8 value. 11-1 moci ity ing the T7 SRC PTF to the TS form, the Tt3 PTF may predict SR from only yl but now has gaineci the errors associated with both T7 and T3. No attempt was made to resleiïne the pdra nieters within T8 considering the new form could contain as many as 24 parameters. The existing parameters in T7 and T3 were used and prediction of SR analyzed. From the first data set (321 data points), in our methodology, each core was saturated and brought to a matric potential (varied from -0.001 to -1.5 MPa) where water con ten t and soil resis tance was nieasured. Using the T3 hction, matric potential and soil properties of each core, 9 values were then calculated. Using thïs calculated 6 value, as well as the matric potential and soil property values once again, soil resistance was then calculated using the T7 SRC PTE Basically, SR was calculated uçirig only the matrïc potential and soil property values of each core, This process of predicting SR data willbe referrecl to as TS prediction. Analysis of Tt3 prediction resulted in a SSE = 1.8 x 10s anda R MSE = 688.6 kPa. The regression of Tâ predic ted vs- measured values showed a rz = 0.79, dn intercept of -41.7 kPa (not sigLificantly different than zero) and a slope of 0.98 (not significantly different than 1). Overaii, the TS mode1 showed a slight loss in performance when compared to the original T7. Using the same process, analysis of T8 performance on the independent data set (164 data points) resulted in a SSE = 5-83 x 107 and a RMSE = 613.2 Wa. The regression of T8 predicted vs. nieasured values (Figure 214) showed a r' = 0.77, an intercept of 159.1 kPa (significan tly different than zero) and a slope of 0-93 (significantly different than one). Based on the SEand RMSE the TS PTF actualiy shows a slight improvement over the T7 fom The T8 PTF however, does show a slight shift by over-predictïng SR at lower resistances in this data set- SSE = 5.83€+7 RMSE = 613.2 N = 164 O 2000 4000 6000 Measured soil resistance (kPa) 2.14. vs. l Figure Cornparison ofT8 predicted measured values of the independent data set- It has been determined that modification of the T7 SRC function to the Tt3 fom did not detrimentaily alter the PTF prediction of resistance to penetration. For the purposes of this study however, we must be able to determine a \y value at a givm SR- Unfortunately, 17ec-d use TS is so camples, i t is nlgebraically impossible to transform T8 into a function that predicts 111 from a given SR. To circumvent this problem, determination of y at a given SR can be done by an iterative method using either a 'solver' function in Excel6.O or by writirig an iterative program. This method defines a dependent variable (SR) which is given to be a specific value (for example SR = 2000 kPa) and through the iterative process changes the iticlependen t va ria ble (11') wi thin Tt3 to achieve that specific SR value. Ln this manner a yl value is n ttained tha t predicts the given SR value. Using this y, value and T3, the corresponding 8 value can then be found, i.e. the volumetric water content of the soil in which the soil resistance has the reached 2000 kPa. To evaiuate this iterative method of deterinining q~ and then calculating 8, the second data set was again used to generate yr v,i l ues. For the second da ta set, a simple item tive program was developed to change yr until the TS function's predicted SR value equaied the measured SR value. Using the value derived from the program and T3, the corresponding 8 value was cakuiated. Predicted 8 values were then compared to the rneasured 8 values within the cores. Prediction of 8 through this method resulted in a SSE = 0.183 and a RMSE = 0-036 cm3/cm3. Results of the regression of the predicted vs. measured 8 values (Figure 215) showed a r2 = 0.84, an in tercep t of 0.050 cm3/ cm3 (significantly different than zero) and a dope of 0.88 (significan tly differen t than 1). OveralI, using this process, for a given soi1 resistance to penetration we can adequately predict the corresponding volumetric water content- SSE = 0.183 RMSE = 0.036 N = 164 0.0 : 1 O 0.1 0.2 0.3 0-4 0.5 0.6 M easured water contents (crn?cm3) Figure 2.1 5. Conipa rison of predicted 8 values using the Tg-iterative method vs. measured 8 values for second data set (164 data points). 2.4 CONCLUSION Validation of the WRC and SRC pedotransfer functions deterrnined by da Silva and Kay (1997) found both to be inaciequate in their prediction. The da Silva and Kay (1997) W RC function (DS1) showed a wide spread in prediction of volumetric water content as well as an uneven distribution of residuals, indicating that the functional Çorm may not be adequate to descnbe the WRC- The da Silva and Kay (1997) SRC function (DS2) showed very inaccurate prediction with very little cohesion of the data with the functional form. To attain better fits for our data Further attempts were made to determine more accura te ped O tra nsfer functions. To achieve more accurate hrnctions, soils were divîded ïnto 4 textural classes (Sand, Clay, Loam-Sand, Loam-Clay) to reduce some of the variability iriherent in Our data. Also, the varïabIes voiumetric water content (9), porosity and Bd were altered to account for swelling. The new WRC function (T3)used a simplified Van Genuchten equation and was found to more accurately predict 9 values than DSl or DESORPMOD (McBride and Mackintosh 1984) using independent data sets. The new SRC function (3)used a combination of ternis encompassing the separate contributions of the liquid phase (effective stress) and the solid phase (the effects of organic and mineral cementation, and friction). The Tt3 function was found to most accurately predict resistance to penetration tor its clerivation data set as well as an independent data set. For the purposes of this study, criticdl water contents for plant growth can also be detennined using both functions. The T3 function was found to more accurately predict the critical points of field capacity and pemtanen t wilting point when cornpared to DS1. The T8 function, while not con~pctredto DS2, was founci to accurci tely predict 0 values at a given resistance to penetra tion. Therefore it can be seen that the two new pedotransfer function T3 and T8 can adequately predict the WRC and SRC usïng the soil paranieters of texture, OC and Bd. These predictions encompass a large range in soil properties but must undergo fui-ther testing to determine if the relationships hold outside of the ranges in which they were ~ie1-1ved. 2.5 REFERENCES Bishop, A.W. 1959. The p~cipleof effective stress. Teknkk Ukeblad, 39,859-863. Bishop, A.W., Blight, GE. 1960. Some aspects of effective stress in saturated and partly saturated soils- Geotechnique, 13:177-197. Bounia, J., and H.A.J. van Lanen. 1987. Transfer functions and threshold values from soiL characteristics to land qualities- Pp. 106-111. In Quantifiecl land evaluation, Proc. Worksti. lSSS/SSSA, Washington, DC- [TC Publ., Enshede, the Netherlands. Busscher, W.J. 1990. Adjustrnent of flat-tipped penetrometer resistance data to a common water content, Trans. ASAE 33: 519-524- Cambardella, C- A., T-B. Moom~an,j-M. Novak, T.B. Parkin, D.L. Karlcn, R.F. Ruco, and A.E. Konopkci. 1994. Field-szale variability of soi1 properties in central Iowa soils. Soil Sci. Soc. Am. 1. 58:150 1-1 57 1 Colvin, T.S., D.B. Jaynes, and D.L. Karlen. 1996. Yield variability within a central Iowa Field. Trans. ASAE- 40(4): 883-889. da Silva, A.P., Kay, B.D. 1997. Estirnating the least limiting water range of soils from properties and management. Soi1 Sci. Soc. Am. j. 612377-883. Crencen, E.L. 1986. Root response to soil rnechanical properties. Trans. 13tll Congress Lntem. Soc. Soil Sci., Hamburg, Cermany. 5:20-47. Hiiiel, D. 1980. Stress-Strain ReIa tions and Soil Strength. (rr. Fundarnentals of Soil Physics. Academic Press. Toronto, pp. 318-352. Leij, C.J., Alves, W.J., van Genuch ten, M.Th., W iiiïarns, 1.R. 1996. Unsaturated soil hydraulic ci d tnbcise, U NSODA 1.O User's Manual. US. Environmental Protection Agency, Ada, OkIahoma, Report EPA/ 6OO/ fi-96/095,103pp. Minasny, B-, McBratney, A-B., Bristow, K.L. 1999- Cornparison of different approaches to the development of pedotransfer functions for water retention curves- Geoderma 93225-253. McBrïde, R.A., Mackintosh, E.E. 1984. Soil survey interpretations from water retention data: 1, Developnient and validation of a water retention model. Soi1 Sci- Soc. Am. J. 48:1338- 1343, Rengasamy, P., Greene, RSB., Ford, G.W. 19S4. The role of clay fraction in the partîcle arrangement and stabïiity of soii aggregates - a review. Clay Research. Vol. 3, No2 53- 67. Çheldrick, B.H., Wanp, C. 1993. Particle Size Distribution. Ln: Soi1 Sarnphg and Methods of Analysis, M. R. Carter, Ed. PP: 499-511. Canadian Society of Soil Science. Lewis Publishers. Taylor, HM., Roberson, G.M., Parker, Ir., J.J.1966- Soil strength root penetration relations for medium to coarse textured soi1 ma terials. Soil Sci. 102:lB-22. Tietje, O. Tdpkerihinrichs, M. 1993. Evaluation of pedotransfer Functions. Soil Sci. Soc. Am.J. 57:lOSS-1095. Topp, G.C., Galganov, Y.T., BaU, B.C., Carter, M.R. 2993. Soi1 Water Desorption Curves. In: Soi1 Sampling and Methods of Analysis, M.R. Carter, Ed, Pp: 569-579. Canadian Society of Soil Science. Lewis Publishers. L.'=iii Lenuctiten, i'vl.TI-i- 1980. A closecl-form equation for predicting the hydraulic corid uctivi ty O t unsa tura ted so ils. Soil Sci. Soc. Ani. J. 44892-898. Wosten, J.H.M., Finke, P.A., Jansen, M.J.W. 1995. Comparison of class and continuous pedo tram fer hinc tions to genera te soi1 hydraulic characteristics. Geoderma 66227-237- Young, LM, Montagu, K., Conroy, J., Bengough, A.G. 1997. Mechanical irnpedance of mot growth directly reduces leaf elongation rates of cereals. New Phytol. 135: 613-619. APPENDIX 2.1 The general form of the T3 l'TF was of the form: 8? = Bs - Br +& I + (a*Iqt 1)") where: 8s = por2 8r = (a + b*%clay + c7%OC + diBif) a = (e + f* X clay + g*% OC + h*Bd) n = (i t j*%day+ k*%OC+- 1"Bd) and a. ,./are constants. Ai parameters are significant to the pc0.05 level unless otherwise noted. For the Sand T3 PTF: ble 2-6. Parameter estimates for the Sand water release curve hction. Pi r-ctcr: Estimate: Asymptotic Std. Error: rl 0.0556 0,0092 b N/A c' O.CM3 0.078 d N/A e 377-7418 44.4402 f 4.9023 1.1000 K -37.2393 6.2776 h -141-2.139 27.8188 1 2.3337 0.3073 I -0.0193 0.0232 k -0.3494 0.0799 N = 162 PXSE = 0.028 an3/an3 * sigruhcant to p = 0.1, " not si&cant to p = 0.1, N/A = parameter not present in model. l 0.0 . 1 4 I 1 0.0 0.1 0.2 0.3 0.4 0.5 0.6 M easured water contents (cm3/cm3) Figurc 2.lh. Cornpitrison oFT3(Sand) predicted vs. measured vdues of volumn~rii.w~iLer ~-oiiLeiit (162 ditta points). For the Clay T3 PTF- Table 27,Parameter esümates for the Clay water release cunre function- Pax-ameter: Estimate: Asymptotic Stcl. Errm I 1.8997 1 0,2489 N = YI5 PWlSE = 0.030 un3/m3 'siy,~uCiiiiiit tm p = 0-1, - IIOL ~igiufiiantto p = 0-1, N/ A = parameter not present in model. -Y, w c.'= 0h6 0.5 71 n- n- I 5 5 0.4 j m - m 0.3 ! a C - 9 0.2 -0 ; 0.1. 0.0 - , 0.0 0.1 0.2 0-3 0.4 0.5 0.6 0.7 Measured water contents (crn31cm3) Figure 2.17. Cornparison of T3(CIay) preclicted vs. measured values of volumelric water content (1306 data points). For the Loam-Clay T3 Table 28. Parameter estimates for the Loam-Clay water release curve function- Parameter: Estimate: Asymptoüc Std. *or: ' 0.0 , 7 0.0 0.1 0.2 0.3 0.4 0.5 0.6 Measured water contents (cm31cm3) Figure 2-18.Cornparison of T3(Lom-Clay) predicted vs. measured values of volunwtric water content (1301 data points). For the Loam-Sand T3 Table 29. Parameter estimates for the Loam-Sand water release curve function. Parameter: Es timate: Asyniptotic Std- Errorr a -0.6678 0.0571 b 0,0028 0.0004 L- o-osn 0.00~ d U.437.l 0.0323 e 165-4473 21 -8756 -l L 1 " sigdi~citittu p = O. 1, " no^ signific'ant to p = 0.1, N/A = parameter not present in model. 0.0 i 1 1 0.0 0.1 0.2 0-3 0-4 0.5 0.6 Measured water contents (cm3km3) Fit;ure 2-19. Coiiipariçon of T3(Loani-Scind) prdicteci vs. measured values of volu metrii wa ter content (643 data points). The general form of the T7 MFwas of the form: where: a = (a+b*% day+c*%OC+d*Bdz) p = (e+f*%day+g*% 0Cih*Bd2) b, = (i+jj%day+k"% 0C+l*Bd2) and a.. .,L z are constants. Ail parame ters are significant to the pc0.05 Ievel unless O therwiç.e noted. In two instances function parameters were not statisticdy significant but were found to greatly Lie~~easethe errors iri prediction aiid therefore kept withii~the model. Table 2-10. Pilrarneter estimates for the Sand soi1 resistance curve hction. Parameter: Estimate: Asyrnptotic Std- Error: k -0,3834 0.1281 1 -2.1557 0.642s z 0.0448" 0.0553 N =32 RMSE = 377.22 kPa * sipdic- an^ 10 p = 0.1, " ncit sip,iiific'dnt to p = 0.1, N/A = parameter not present in modd. I I 1 1 i 1 O 500 1000 1500 2000 2500 3000 Measured soi1 resistance (kPa) Fi ye2.20. Cornparison of T7(Sand) predicted vs. measured values of soîi resistance (32 data points- htdata set), For the Clay T7 Table 211. Parameter estimates for the Clay soil resistance curve hction. Parame ter &tirnate: Asymp totic Std, &or: z 0.2530 0.0321 = 166 RMSE- -- - = 785-26 kPa I N 1 * significciii~tu p = 0.1, " 1101 ~i~;~ûficantto p = 0.1, N/A = parameter not present in model. 2000 4000 6000 8000 Measured soi1 resistance (kPa) Figure 2.21. Cvnipcirisoii uf T3(CIay) predicted vs. measured values of soi1 rcsistance (196 data points- first data set). For the Loarn-Clay T7 PTF: Table 212 Parameter estimates for the Loam-Clay soi1 resistance curve hction. I Estimate: I Asymptotic Std. Error: I L 1 WA z 0.3253 0.0251 N =32 PWlSE = 476.63 kPa I " sil;niiiiciii~tu p = 11.7, "* not sit;nificant to p = 0.1, N/A = parameter not present in model. O 1000 2000 3000 4000 5000 M easured sail resistance (kPa) Fi);ri ri* 2-27. Cc,nipi riscin of T7(Lciani-Clci y) prerliz~dvs. masureci values of soi1 rr!sis~criiic(74&ta FOUILS- first data set). For the Loam-Sand T7 PTF: Table 213, Parameter estimates for the Loam-Sand soil resistance curve hction. Parame ter: Es timate: Asymptotic Std-Errorr I z 1 0.3146 0.0279 N = 142 RMSE = 637.59 kPa ' siyiiifii~ii~tu p = O.I. - not signiticant to p = 0.1, N/ A = parameter not present in modeL M easured soi1 resistance (kPa) CHAPTER 3 : THE SENSITIVITY OF CORN (Zea mays) YIELD TO THE LEAST LIMITING WATER RANGE OF SOU 3-1 BACKGROUND Agricultural fields Vary considerably in their soil properties, landscape features, and management histones. This variability has been shown to contribute to variation in yieid. Colvin et al, (1996) described the yield patterns for corn and soybeans in rotation after six consecutive years within a single field. They found that certain locations within the field had consistently high, consistently low, or erratic yields when compared to whole field averages. Much of the variation in yield can be measured with current technology, but the root causes of thiç spatial variability are unexplained. The goal of this project was to assess the influence of soil structure and water content on the spatial variability in yield. 1 t is assunieci tha t the iinportance of soii structure upon yield is related to the soil's a bility to provide oxygen, water and support the growth of roots. The parameter Non- Lirniting Water Range (NLWR), introduced by Letey (1985), later renamed Least Lirniting Water Range (LLWR) has ken used as a characteristic of soil structure (da Silva and Kay, 1997). The term Least Limiting Water Range is defined as the range in soil water content à tter rapid drainage has ceased within which Linütations to plant growth associated with water potentia1, aeration and nech ha ni cal resistance to root penetration are minirnal (da Silva and Kay, 1997). The LLWR is a range, defined by an upper limït and a lower Limit. The upper limit value is chosen as the Iower value of water content in which aeration to the roots becomes lin~iting,or w hen ra pid drainage ceases. Aera tion was concluded to be lùniting at an air- filled porosity of 0.1 cm3/cm3 (Grable and Siemer, 1968), and rapid drainage was concluded to cease a t field capacify (FC) at a water potential of -0.01 ma(Haise et al. 1955)- The lower tinut values were chosen as the greater value of the water content bdow which water cannot be extracted by plants (permanent wilting point or -1-5 MPa) fourid by Richards and Weaver (1944), or the water content at which mechanical impedance restricts root growth. Cone penetrometer resistance is comrnonly used to simulate the impedance encountered by plant roots. Young et al. (1997)found that mechanical impedance of root growth directly dffected plant growth, and based on studies done by Taylor et al., (1966) and Greacen (1986), a cone resistance of 2 MPa was used as the upper iïmit of penetration pressure exerted by the roots of most field crops. From this, the other criterion for the lower LLWR Limit was based on the water content in which the soil's penetration resistance exceeds 2MPa. In essence it is hypothesized that the LLWR can be used as a measure of the soil's abiiity to provide water, air and a favorable enviromnent for root development and as such, the magnitude of the LLWR will be positively correlated with yields- tt stands to reason that a sod with a wider LLWR will have a greater ability to provide water, air and root development and thus have greater yiefds. It is further hypothesized that crop growth will be negatively correlated to the frequency in which seasonal water contents fail outside the LLW R (Fil,,)- Here, it is reasoned that as the soi1 drïes durùig the growing season, the n uinber of seasonal wa ter contents nieasured below the lower limits will increase and yields will be negatively affecteci. This reasoning is also applicable to seasonal water contents méasured above the upper liinits. Seasonal water contents rising above the upper Mts would induce aeration problens and thus also negatively affect yields. These hypotheses are supported by work done by da Silva and Kay (1997) where they used both the LLWR and Fil,, (in the 0-20cm depth) to assess shoot growth of corn. They found tha t shoot gro w th was indeed positively correlated with the magnitude of the LWLR and negatively correlated with Fu,. The effects of the LLWR and Fu, upon yields however, are unknown. This project wiii attempt to determine the relationship between soi1 structure, seasonal water contents and final yields of corn (Zea mays). Stypa et al. (1987), in a study of corn root growth, found that over 80% of total root length was in the 0-30 cmdepth. It is assumed that if there is a relationship between soil stiucture, soi1 water and yields, the relationship wiU be seen in the top 30cm depth. Therefore, the objectives of this study were to: (a) detem~ethe degree in which the magnitude of the LLWR in the 0-30cm depth could explain variation in yields of and, (b) deternune the degree in which the frequency of seasonal water contents falling outside of the LLWR (Fu,,) in the 0-30- depth could explain the variation in yields of corn (Zea mays). The study will be focused on corn crops from 12 sites across southern Ontario, conducted over the two growing seasons of 1998 and 1999. 3.2 METHODS AND MATERIALS This study was conducted upon 6 farms during the 1998 growing season and 4 farms during the 1999 growuig season. AU sites were located between Thamesville and Beeton, Ontario, Canada (Figure 3.1). ALI farms were planted to corn (Zea mays) in the season of sampling. Tiliage upon all famis was either conventional till or zero-all management pable 3-1)- Figure 3.1. Map of sites in southern Ontario. To characterize each site, plots were selected on the basb of landscape position to achieve varia bility in yield, seasonal water content and soil properties. The experimental design of this project was a factorial experiment using randomized complete block design with several replications, each with several plots divided by landscape position and 2 treatments: 150kg/ha N fertilization and no N fertiLization. Eight of the farms were each characterized by estabhshing 24 plots: 4 repiicates, each with the 2 N treatments, and 3 landscape positions: upper slope, niid-dope and toe-slope positions. The remainirig sites were located at the Elora Research Station where each site was characterîzed by 30 plots: 3 replicates with 2 N treatments and 5 landscape positions (Upper slope, shoulder, mid-slope, lower slope and toe-slope). For all farrns, plots were approximately 5m long and 6 rows wide, At the start of each growing season, four sets of Tirne-Domain Reflectometry PR) probes, 30cm in dep th, were ins ta lied vertically (15cm from the corn row) in each plot. Volumetric water content was measured weekly, starting shortly after seedling emergence and N fertLLization. At the completion of each growing season, pnor to harvest, 2 undisturbed cores (5cm diameter x 2.5cm height) were taken next to each set of TDR probes. Overall, 8 cores were taken frori~each plot, four cores at 5-7.5cm depth and another four sores were taken at 20-22.5~111~iepth, In all, 2076 cores were coilected. Each core was wrappeci in cellophane and stored at 4OC until used for analysis. Lmmediately after core collection, a 6 metre Length of corn row was hand harvested in each plot. The harvested comcobs were kiin dried for several weeks, shelled and weighed to calculate final yields. Crdin yields are expressed on a dry weight basis. Soi1 troni racti core wds split into 2 parts; one part was sieved (2mm) and used for particle-size analysis; the other was ground and used for OC analysis. Particle size analysis was done using the hydrometer method and calibrated with the pipette method (Sheldrick and Wang, 1993). Organic carbon analysis was done using the LEC0 SC 444. Pedotransfer functions (PTF) relating the water release cuve and soil resistance curve with clay content, OC and Bd were developed (Chapter 2) and used to calcdate available water capacity (AWC) and the LLWR for each plot. The critical water contents at field capacity (Ofc) and the permanent wilting point (e,,) were caldated using the T3 WRC MF. The volumetric water content at 2 MPa soi1 resistance (es,)was calculated using the T8 SRC MFand the volurnetnc water content at 10%air-Fiiled porosity (&@)was calculated as: Ba$ = (1 - Bd/Pd) - 0.1 where Bd = bulk density, and Pd is an assumed particle density of 265 g/cm3. The AWC was calcula ted as: Regression analysis (SAS), linear and nonlinear, were used to evaluate the rela tionships between yield (+N) with the LLW R, Fu,, and O ther soil properties. EvaIuation of yields, seasonal water and soil properties were restricted to N fertilized treatments only. I t was assumed that the yields measured within the +N heatments were not nutrient limited and the variation in yields were affected by only soil water and soil structural effects. 3.3 RESULTS AND DISCUSSION Textural analysis of the cores withïn the +N treatments showed that our data ranged from 0- 60.3% clay content and 3.2- 92.8% sand content, Organic carbon and Bd ranged from 0.25-5.88% and 1.05- 1-79 g/cd, respectively. A summary of d soil properties is shown in Table 3.1, Prelin~iiwrvmalysis of Our data was done to determine if seasonal water played a role in influencing the variations in yields- Using £inal yield values in the +N treatments and the average meaçued water content readuigs taken duririg the growing season (8-,) regression analyses were done. Correlations of yields (+N) with 0- were found to be significant (p<0.05) in 6 of our 12 sites. One other site (Elora no till1998) also showed a correlation signiticant to the p<0.10 Irvel. The site determined to have the best correlation between yield and e,.,, was the Cameron site with a r2 = 0.826. Results of this preLiminary regression analyses can be seen in Table 3.2 Soi1 properties found in the core analyses were used to calculate the LLWR using the W RC and SRC pedotransfer functions. The LLWR values were then averaged by depth and wi thin raïh plot. Although the liiiiiting factor deternUning the upper and lower hitsof the LLW R varied, the water content at 10% air-filied porosity and soi1 resistance defined the upper and Iower LLWR linut 79% and 96% of the tirne, respectively. Statistical averages of the calculated LLWR, Fil,, and yield values in the +N treatments for ail fanns are shown in Table 3.3. ln general, the magnitudes of the LLWR (upper limit minus the lower Mt) defineci across nmny of the Farti-is were faund to be very narrow. Ln some instances the Table 3.1. Summary of soi1 properties for all plots in each site (0-30cm depth). Buik Density Organic Fann: (dm3) Carbon (99) Sand(%) Clay(%) EC98: Elora 1998 Average: (conv. till) St. Dev.: Minimum: Maximum: E98: Hora 1998 Average: (no M) St. Dev.: Minimum: Maximum: ECSY: Eiorü 1999 Averir ge: (conv. till) St. Dev.: Minimuni: Müximuni: E99: Elora 1999 Average: (no tiil) St. Dev.: Minimum: Maximum: McCracken (no Average: St. Dev.: Miiurii uni : Maxim uni : Portolinski Average: (conv. tiU) SI. Dev.: Minimum: Maximum: CN: Canagra Average: North St, Dev.: (no tiii) Muiim uni : Maximum: CS: Canilb~ii A vert ge: Nor111 SL.Dcv,: (iviiv. ~ill) Miiiin~uni: M~xiuiuui: CC: Caiiigra A vcriige: Suuth St. Dev.: (no kiki) MUlin1un1: Ma xini uni: Denys (no ta) A vwdge: St. Dev.: Mininiurn: Ma xini uni: C~\nierun(110 Average: till) St. Dev.: Minim uni : Maxiaiuui: Newcombr (no Average: ta> St. Dev.: Mulinluni: Maximum: Table 3.2. Results of regression analyses between yield (+N) and measured seasonal average wa ter contents (O,,). Farm : Regession Parameters: Pre diction: EC98: Elora 1998 YieId (+N) = -9820 + 5348-1.Ot'(8,,) R2 = 0.3% (conv. till) ÇÇE=389xlW Yield (+N) = %25St 1 t exp(43.761$*(9,- 0.1263t)) R2 = n/a SSE= 229 x1W E98: Elora 1998 Yield (+N) = 1664.6 t 32507.0$*(0,) R= = 0.251 (no tiIl) EC99 Elora 1999 Y ield (+N) = -818.3 + 42384.@*(0,,) (conv. t il 1) E99: Eluri 199) (no till) McCracken (no tiiL) Y ieId (+N) = 9437-2-f+ 9936.9-1"(8,,) Rz = 0.340 SSE = 1.28 x 107 Yield (+N) = 12639.7t 1 + esp(-19.46*(0, - 0.05)) Podolinski (cunv. till) CN: Canagrci North Yield (+NI = 3911-8$ + 14806.0*(8,,) (no till) CS: Canagra North (conv. till) CC:finagra South (no till) Denys (tir) tili) Yicl J (+N) = 3322.0t + 38673.(It'(8,,) R'- = 0.826 SSE = 8.92 x lOo Yield (+N) = 1 6054.7t R- = n/a 1 + tx~(-lO,83*(8, - O. 123$)) SSE = 8.6û x 10b Newcondw (rio tiII) Y ieid (+N) = 6846.6t + 6578.1*(8,) t = rcgrr~ssirmsil;~iific.Liii~ (p<0.05), $ = regressioii sigiiificant (p<0.10), d other parameter estimates Linu Ii~uiilliio~ sil;nil'ic-~n~. Rz v~iluesfor lion-liiiear regressions codd not be deterrnined. Cornparison was done using SSE. Table 3.3. Statistical data for LLW R, Fu,, and fïnd yields (+N treatments, 0-30cm dep th). LLWR magnitude Fu, Final Yields Farrn : (cm3/cm3): (9; 1: &g/W EC98: Elorci 1998 Mes: (conv- W) Std- Dev.: Minimum: Maximum: E98: Elora 1998 Mean: (no till) Std, Dev.: Minimum: Maximum: EC99: Elora 1999 Mean: (conv- till) Std. Dm.: Minim uni : M~ixin~uni: E99: Elorii 1 %Y Mean: (no till) Std. Dev.: Minimum: Maximum: McCracken Mean: (no till) Std. Dev.: Minimum: Maximum: Po Joliiiski MC~II: (c-c) iiv. till) SLJ. Dev.: M inioi um : M~iximuni: CN: Guiagrii Mem: North Std. Dev.: (no îdi) Minimum: Maximum: CS: Canagra Mean: North Std. Dev.: (conv. ta) Mirumuni: Mdxinium: CC:Cd Ild );rd Meciri: sciu111 StJ. Dev.: (no ta) Mriunl uni: Mcr xini uni : Denys (no till) Mean: Std. Dev.: Minin1um: Maximum: Cameron Mean: (no till) Std. Dev.: Minim u m : M~xiriiuni: Newiom hc (nu Memx tiu) Stcl. Dev.: Muiinium: Table 3.4. Rdtsof regression analyses between yield (+N) data and the LLW R, Fh. Fann: Regression Parameters: Prediction: EC98: Elora 1998 Yiaid (+N) = 6639.8t + 651.6'(LLWR) (conv. till) Yieid (+N) = 10236.û-t - 43.5*(Fuw) E98: Elora 1998 YieId (+N) = 7655.3-t - 20941i(LLWR) (no till) Yield (+N) = 6479.7f + 11.9*fi,) ECm Elora 19% Yield (+N) = 7464.6t + 5816.W(LLWR) (conv. till) Yieici (+N) = 7723.2t + 3.4*(Fu,) EW: Elora 1953 UieId(+N) = 53633t + 15W0t*(LLWR) (no till) Y ield (+N) = 95337t - ~O-I~*(FU~~) McCracken (rio till) Yield (+N) = 12447.q - 41612*(LLWR) Yield (+N) = 11482û-f+ 129'(Fu,) Podolinski (conv. till) Yield (+N)= 10759.û-t + 28206.w*(LLWR) Y ieid (+N) = 17759.w - 70.8Y(FuW) CN: Canagra North Yield (+N) = 72139t - ïl66.1*(LLWR) (no till) Y ield (+N)= -3732-9 -t 106.0*(Fu,,) Y irici (+N)= 8c134.4t - 19923.w*(LLWR) YielJ (+N)= 16330 + 56.2$"(FuW,) CC: Ciinagri South Yield (+N) = 4229.6t + 8861.tP(LLWR) (no till) YieId (+N) = 163330 - 119-5*(F~wr) Denys (nu till) Y ield (+N) = 8380.3t + 1020-F(LLWR) Yield (+N) = 6983.8t + 16.1i(Fu,,) Yield (+N) = 117U.Iy- - 7613.4*(LLWR) Yidd (+N) = 10555.ût + 7.8*(Fuw) Newcoilihe (nu till) Yield (+N)= 8275.2-f.- 381.5*(LLWR) Yield (+N) = 7947.5t + 3.3*(FuW) t = regression significant (pc0.05), * = regression significant (p<0.10), aU O ther parameter estirnates are found not signhcmt. LLWR magnitude was found to be zero and as a redtseasond water contents fell outside of the LLWR 100% of the time. These values of Fu, imply that 100% of the measured soil water content values were founci to be critically limiting to the plant. h general, occurrences of soi1 water content falling outside of the LLWR were occurrences below the lower ktt Statistical results for each farm cmbe seen in Table 3.4. Of our 12 sites, only the Podolinski site and the Elora (no till) 1999 site showed a significant positive relationship between yield and the LLW R magnitude, and a signScant negative reiationship betweeri final yield and Fii,,. Exain ples of these reid tionships cm be seen from the Elora (no till) 1999 site in Figures 3.2a and 3.2b. Conversely, the CS-Canagra North (conv. till) site reveaied a sipificant nega tive relationship be tween y ield and LLW R magnitude (Figure 3.3). Despite this Canagra site showing a result opposite to our first hypothesiç, this site showed the best correlation between yield and the LLWR with a rk0.75. L Figure 3.2a,b. Plot of the Elora (no till) 1999 yield data relationship with the LLWR and Fu,. Figure 3.3. Plot of Canagra North (conventional tu) yield data relationship with the LLWR. Overall across our 12 sites, it cm be seen that the LLWR, combined with seasonal water content data (Fiiw,), did not play significant roles in explaining the variations in yields. &O, - we ~nustconsider that pIants did grow and yields were obtained across the various farms yet in the majority of sites dnd for the mdjority of the growïng season, the water contents were calculated to be criticaiiy linùtirig. Within the Elora (no tiL1) 1999 data (Figure 3.2b) it can be seen that a yield of approxirnately 5000 kg/ha (57%of maximum yield for the site) was achieved yet 100%of the soil water readings taken throughout the season were found to be critically liriiiting- W hile these results raise many questions about the validity of using the LLWR and Fil,, it is in teresting to note that da Silva and Kay (1997) reported that despite Fil,, values of 100%, shoot growth was stili measured to be greater than 4 cm/day. Their data however, also showed significant positive relationships between shoot growth and the LLWR, as well as significant negative correlations between shoot growth and Fu,. Clearly our da ta show that neither the LLWR nor Fir,, measured in the top 30cm, are ddeq ua te in ex plduiing va ria tion in yield. Therefore, either our hypo theses conceming the LLWR and Frr,,., and their effectson yields are incorrect, or errors were made in defining/calculating the seasonal water contents and the least lïmiting water range for corn. Conceptually, it is difficult to imagine that as the frequency of limiting conditions for plant gïowth increase, the pIant wiU not suffer a decrease in yieId. Therefore possible errors made in calcdating the LLW R were assessed. To determine the sources of the errors, attention was first direct to the calculation of the LLWR. The most iimitirig water contents were generally found to be 10%air filled porosity and soil resistance. The cdculation of 10% air fiUed porosity was a simple calcdation and deemed unLikely to be a source of error. &O, the majority of measured seasonal water contents were found to fall below the lower linut- Therefore calculation of the soil resistance Lïn~twas exmüned. Data on measured water contents suggested that the Iower 1uiUt of the LLWR may have been too high or that yields were less responsive to soil resistance measured over the 0-30cm depth than were the growth rates observed by da Silva and Kay (1997). The lower luriit n-iay have been too high because of errors in estirnating the wà ter content d t ii soi1 resistance of 2MPa or the Limiting soi1 resistance of 2MPa was too low. The PTF for the SRC predicted the penetration resistance of soil as a function of soil n~atricpotential and soil properties. The T8 SRC PTF was of the fom: SR = a@ + p(€3/poro~ity)s(vx) where SR = soil resistance &Pa), a = (a+b"%clay+c"% O.C.+d*Bd), p =(e+ f*%clay+g*%O.C.+h"Bd), 6 = (i+j"%clay+k*%O.C.+l"Bd), al1 8 values are replaced by the T3 W RC MF, and a...l,x are constants. When given the measured soil resistance, the T8 function was used to predict the volumetric water content at which the measurement was taken and was found to predict dpproxirna tely 84% of the variation in 9, in an independent data set, with a RMSE = 0.036 ~1i+/cn13 (Figure 3.4a). For cornparison the same analysis was done using DS2, the SRC lTF fourid by da Silva and Kay (1997). Given ihe measured soil resistance values, volumetric water content was predicted using the DS2 mode1 and was found to predict approxiniately 68 '% of the variation in 8, with a RMSE = 0.083 cm3/cm3 (Figure 3-4b). Figure 3.4 a,b. Prediction of water contents by the (a) T8 and @) DS2 SRC hinctions vs. measured values for an independent data set (164 data points). I t can be seen that within this independent data set the T8 function shows a more accurate prediction. The DS2 function however consistently underpredicts water contents at the dry end of the analysis (Le. the ared of high soi1 resistance). Presuming for a moment that the measured da ta for the independen t da ta set is incorrect and the DS2 prediction is correct, the water contents predicted by DS2 would result in wider LLWR magnitudes and presumably reduce the frequency of seasonal water contents falling outside the LLWR. In general however, there is no evidence to indicate that methodology and prediction of the cri tica i wa ter content a t 2M Pa soi1 resistance using the T8 function, is at fault in describing the LLW R. Porho ps a redefinition of the SR limit to a value greater than 2MPa might improve on Our original analyses. In the following analyses however, data suggests that redefining the SR limit to a higher Limit would not be a fruitfd exercise. Considering that the majority of Our measured seasonal water contents were found to fa11 below the lower liiiiit of the LLWR, perhaps a reanalysis of Our data using the PWP as the lower limit instead of the SR iimit would improve our predictions of "Limiting" water conditions. Analysis was done to test if the frequency of seasonal water contents fahg below the PWP (Fpwp) could better explain some of the variation found in ouyield data (field capacity and 10%air füled porosity were not considered in this analysis because seasonal water content rarely surpassed the upper lirnit). Overall, it was found that FPw, showed no significant relationship with yield for ail farms (example Elora conv. till1999 - Figure 3 -5). Figure 3.5. Plot of yield (+N) vs. the frequency of water contents fahgbelow the permanent wiiting point during the growîng season (Fpv) at the Elora (conv. till) 1999 site. Clearly, despite altering the lower limit of the LLWR from SR to the PWP, understanding of the variation in yielcls dicl not improve. Also, the value, Fpwpf was still found to be high. In Figure 3.5 it can be seen thcit although over 60% of the seasonal water content readirigs were found below the PW P, yields of over 8000 kg/ha were still achieved. Analysis was done to determine if the T3 PTF prediction of the PWP was at fault and consistently over-predicted -1.5MPa conditions. To achieve this, T3 predictions of the -1.5 MPa potential were done on the original data set used by da Silva and Kay (1997). To compare, DESORPMOD, d PTF derivéid by McBride and Mackintosh (1984), was also used for a third reference, Resultç of thiç analysis showed that both T3 and DESORPMOD consistently over-predicted the da Silva and Kay (1997) data (Figure 3.6a and Figure 3.6b, respectively), but when compared to each other, T3 and DESORPMOD predictions were similar (Figure 3.6~).Therefore, it can be seen that T3 predictions of the PWP are not consistently different than those found by another model, and therefore it is urilikely that MT prediction of the PWP in our analyses thusfar is the soume of our errors. 0.0 0.1 02 03 0.4 Measued water caiterûs (m'lem) l3and DESORPMOD Prediclion of -1.SMPa DaSiiva Data Figure 3.6 a,b,c. T3, DESORPMOD predictions relative to each other using cla Silva and Kay (1997) data. Further analysis of seasonal water data revealed that in many sites, the recorded seasonal soii water values were weU below the measured PWP values. In order to remove error associa ted w ith predicting the PW P from PTFs, the minimum recorded soil water values were compared against actual core data. Across aii farms in 1998,2 of the 8 soil cores taken (1 at each depth) from half of ail plots were chosen to undergo water release laboratory analysis. Volumetrïc water content meanired at -1.5 MPa hom both cores were averaged to gïve an average PWP value for the 0-30cm depth. Only two plots showed an extreme change in textural characteristics within the 0-30cm depth and those were eluninated from this analysis. The average PWP value taken from the core water release data was then compared with the nünimum average soi1 water value as measured by the 0- 30cm TDR probes adjacent to the two cores. The difference (minimum recorded TDR value minus the average core PWP value) was found to be on average -0.051 cm3/cm3. The minimum recorded soi1 water values were consistently lower than the measured PWP values except in the upper slope positions at the McCracken farm (Figure 3.7). These pdrticular plots con tainrd high sand contents with very Little organîc carbon. Figure 3.7. Plot of difference values (minimum recorded TDR values during the srowing sedson - core measured PW P) across ail 1998 sites. Whilr it can be seen tliat our PTFs pradicting the PWP are unhely to be directly responsible for our erroneous data, this evidence suggests that our errors may be due to the methodology used in detemiining the -1.5MPa matric potential values in our cores. However, if we are to question our methodology and the validity of our PWP data, we must consider that our predictions of the PWP using the T3 function were similar to predictions made by DESORPMOD in an independent data set Therefore, in questioning the validity of our PWP methodology and data, we also question that of McBnde and Mackintosh (1984). Presuming however, tha t both the T3 and DESORPMOD predictions are faulty and the DS1 data and predictions are a more accurate and realistic depiction of soi1 water conditions, it is conceivable that our nünimum recorded soil water values would not surpass the PWP predicted by DSI. Given the average soil properties for each plot in dl2 sites, the T3 and DSI functions were used to predict the water contents at PWP and were cornparrd with the minimuni nieasured soil water values. Plots of T3 prediction can be seen in Figure 3.Sa and DSl in Figure 3.Sb. Despite the fact that the OS1 mode1 predicted the Iowest soi1 water values for the PWP of all three WRC models tested, it is still evident that many of our rninïmurn recorded soil water values feu far below the lower limit- Figure 3.8 r,b. Cornparison of i~ünimumrecorded soil water values with T3 and DSI PWP predictions. These minimum recorded water contents found below the DSl predicted PWP were at times, also found to correspond with good yields. An example can be seen in Figure 3.9, where in the toe-dope position, water contents were found to falï 0.055 - 0-104crn3/cm3 below the PWP predicted by DS1, yet yields close to 9000 kg/ha were found. Figure 3.9. Pfo t of yield and the niinimum recorded water content minus the DS1 predicted PW P, across landscape positions (CS-Canagra site). Therefore, judging from the presented data and considering that the minimum recorded TDR measured water contents frequently feu below alI measures of the PWP, it is hypothesized that the errors associated with the LLWR and the seasonal water content data are no t caused by prediction errors from the pedotransfer functions- There is also no evidence to show tha t the methodologies were a t fault or significant experimental errors were present. Therefore soil water contents that fell below the PW P may only be explained by (a) loss of soi[ wa ter due to evaporation from the soil, (b) the TDR measurements were consistentlv underestiniating actual soil water, or (c) the critical limits of PWP (-1.5 MPa) and SR a t 2MPa are inadequate in describing the critical water extraction limits for corn. Minimum recorded soiI water values were analyzed for tempord stability to deternune if the values occurred a t relatively the sanie time within the season. Analysis showed that the minimum-recorded vülues were generally around the 5dl- 7th readings (rnid-June to Mid August) in 1998 and 1999. By this time, for most sites, silking had or was occurring and canopy closure was reached. Within the Canagra sites (1998) however, plant growth was extremely poor and canopy closure was not attained within many plots for the entire growing season. Within these plots soil cracking was evident and evaporative loss of soil water was possible, but in general for most plots and most farms, canopy closure was met and the possibility of evaporative loss of soil water to the atrnosphere was reduced. Also, consider that even if evaporation had caused the extremely low measured soil water contents, it is stiil questionable how these extremely low water contents had so Little effect on final yields. In a study done by McNabb and Kay (unpublished data), TDR measured soil water contents were compared with data measured horn actual soil cores- Data was obtained at the Elora Research Station in 1997. Five TDR probes were placed across 5 landscape positions, TDR nieasurenients were taken and then cores were taken adjacent to the probes to measure gravirnetric wa ter contents and buik density. Gravimetric water contenk were converted to voIumetric water content using the measured Bd and then compared to the TDR data. A plot of the converted volumetric water content with the TDR denved volumetric water content (Figure 3.10) resulted in a rz = 0.875, slope of 0.886 (not significan tly ciifferen t than 2) and an in tercep t of 0.042 (nof significantly different than zero). Therefore i t can be seen tha t the TDR data does not stray significantly from an altemate form of volurnetric water content measurement Although this analysis encompasses only five points, the data provides no evidence to explain the magnitude or the consistency of the difference between our measured TDR water contents and our various methods of caiculating the PW P. The possibility of a TDR operator error was also analyzed but was deen-ied un II kely beca use the opera tor for much of Our TDR data was the same for the McNabb and Kay study. ln general, it is deemed that our TDR data was not a major source i 0.15 -l 0.15 0-17 0.19 0.21 0.23 0.25 0.27 0.29 Converted Vol. Water Content (%vol. of soil) Figure 3.10. Plot of volumetric water content values measured by TDR vs. volumetric water content converted h-om gravirnetric samples. Finatly, if ali O ther explana tions can be elirninated, the observed water contents measured throughout the season were within the range of plant extractable water. If so, our data indicate that the water content at 2MPa SR and -1.5 MPa PWP, defmmined under laboratory conditions, may not adequately describe iimiting water contents under field conditions. Certainly thrre have been studies showing that root penehation has occurred in soi1 rcingmg h-oni 3 MPa (Ldboski et dl. 1998) to 5-7 MPa (Cerard et al., 1982) penetration resistance. ln another study, Dexter (1987) suggested that critical root impedance was not static (Le. 2MPa) but moved reIative to the matric potential within the soil. Perhaps these should be considered as more likely critical lirnits for SR. More irnportmtly however, the critical lowltr liiiiit associa ted with the PW P niust be exaniined. As with soil resistance, there 1s Cilso evidrncr showing thdt corn lias the abiiity to extract soi1 water beyond the classical s Linut of -1.5 MPa ~natricpo tential (Cabelguenne and Debaeke, 1998). The nature of a new lower Iunit of plant extractable water however has not been discussed in great detail. If we are to suggest that the PWP should be shifted to a lower matric potential, we must also consider the nature of the WRC. Implications of another 0.05 cm3/cm3 of water that corn piants could transpire (as iç seen in our data), wodd equate to tremendous water potentials at which plants could draw water. For example, the T3 PTF prediction of a water release curve for an average soil from the Podolinski site with 10%sand, 45% clay, 2.3%OC and a Bd of 1.31 g/cm-l, can be seen in Figure 3.11. At a matric potentid of -1.5MPa, the vol. water content was calculated to be approximately 0.28 crn3/cm3. This value was consistent with that of DESORPMOD. implications of a reduction from 0.28 cm3/cm3 to 0.25 cm3/cm3 water content resulted in a rnatric potential of -15 MPa, an order of magnitude higher. Clay Soil: 9.9%sand,44.5%clay, 2,3%OC, 1 .3g/cm3 I Potential (MPa) Figure 3.11. Example of a predicted water release cuve from a clay soil. 3.4 CONCLUSIONS Frorn Our preiïrnhary analyses, it is clear that water (in the fonn of average water content measured during the growing season) in the 0-30cm depth plays a role in explaining yield variation on many of our sites. It was hoped that using these seasonal water values and knowing the linuts in which plants experience water stress, wouid help us in explaining more of that yield variation. From our analyses using the Least Limïting Water Range (LLWR) as defined by da Silva and Kay (1997), it is evident that the LLWR and Fu, the frequency at which seasonal water feu outside the LLWR, were inadequate to describe the soi1 limiting conditions in which plants grow. Ln fact, seasonal water contents were found to fali below both lower limits of the LLWR- Seasonal water contents were found to fa11 well below the 2MPa soil resistance lirrut, as weU as the PWP, whether those values were predicted by the T8 or T3 hctions (Chapter 2), the da Silva and Kay (1997) functions, or dctual corr meas ured -1 SMPa wa ter release data. Upon further analysis, it was found that niethodology, sdlculntion dnd prediction errors were uniikely to be the cause of the poor predictions of yield using the LLW R and Fu,,. Finally, two possibilities remain to explain the poor results fourid. First, that plant extractable water at greater depths than 30 cmmay have played a sigruhcant role in deterininhg final y ieids and second, that water content at 2h4Pa soi1 resistance and PWP are inadequate in describing the critically Litniting water contents for corn growth. Ultimately, Our abiLity to manage the variabilities inherent in agricultural systerns wiU depend in a large part, upon our understanding of soil properties, their interactions with seasonal water and how it ail affects plant growth. It is evident that our current definition of critical soil water conditions are kadequate. Clearly a better definition of the critical lower limit of water content rriust be found. 3-5 REFERENCES Busscher, W, J. 1990- Adjus tmen t of Ba t-tipped penetrometer resis tance data to a common water content. Trans. ASAE 33: 519-524. Cabelguenne, M-, Debaeke, P. 1998. Experimental detennination and modehg of the sorl water extraction capacïties of crops of maize, sunflower, soya bean, sorghum and wheat Plant and Soi(- 202:175-292. CarnbardeLla, C. A., T-B- Moorman, J.M- Novak, T-B. Parkin, D.L. Karlen, R-Fr Ruco, and A.E. Konopka. 1994. Field-scale variability of soil properties in central Iowa soils. Soil Sci. Soc. Am. J- 58:1501-1511 Colvin, T.S., D.B.Jaynes, and D.L. Karlen. 1996. Yield variability within a central Iowa Field. Trans. ASAE. 40(4): 883-889- da Silva, A.P., Kay, 6.D. 1997. Estirnating the least limiting water range of soils from properties and management. Soil Sci. Soc. Am. J. 61:877-883. Dexter, A.R. 1987. Mechanics of root growth. Plant and Soil. 98: 303-312. Grable, A.R-, Siemer, E.G. 1968. Effects of bulk density, aggregate size, and soil water suction on oxygen diffusion, redox potential and elongation of corn roots. Soil Sci. Soc. Ani. Proc. 32'180-'186. Gerard, C.J., Sexton, P., Shaw, G. 1982- Physical factors influencing soil strength and xoot growth. Agrononiy Journal. 74: 875-879. Creacen, E.L. 1986. Root response to soi1 n~echanicalproperties. Trans. 13h Congress Intem. Soc. Soi1 Sci., Hatiiburg, Gern-iany- 5:20-47. Haise, H. R. Hdas, H.J. ,Jensen, L. R. 1955. Soil nioisture studies of sonie Great Plain soils: II. Field ca pacity as rela ted to 1/3-atntosphere percentage and "minimum poinf' as related to 15 and 26- atniosphere percentages. Soil Sci. Soc. Am. Proc. 3420-25. Laboski, C.A.M., Dowdy, R.H., ~llmara&R.R, Lamb J.A. 1998. Soil strength and wafter content influences on corn root distribution in a sandy soil. Plant and Soil. 203: 239-248. Letey, J. 1985. Relationship between soil physical properties and crop productions. Adv. Soil Sci. 1:277-294. McBride, R.A., Mackintosh, E.E. 1984. Soil survey interpretations hem water retentiam data: 1. Development and validation of a water retention model. Soil Sci. Soc. Am. J. 48-:1338- 1343. Richards, L.A., Weaver, L.R. 1944. Fifteen atmosphere percentage as related to the permanent wiltïng point Soil Sci. 56:331-339. Sheldrick, B.H., Wang C. 1993. Particle Size Distribution. In: Soil Sampluig and Methods of Analysis, M.R. Cdrter. Ed. PP: 499-57 1. Canadian Society of Soi1 Science. Lewis Publishers. Stypa, M., Nunez-Barrios, A., Barry, D.A., Miller, M.H., Mitchell, W.A. 1987. Effects of subsoil bulk density, nutrient availability and soil moisture on corn root growth In the field. Can. J. Soi1 Sci. 67: 293-308- Taylor, H.M., Ro berson, C.M., Parker, Jr., J.J. 1966. Soil strength root penetration relations for mediuni to coarse textured soil materials. Soil Sei. 10218-22. Young, LM., Montagu, K., Conroy, J., Bengough, A.G. 1997. Mechanicd impedance ofroot growth directly reduces leaf elongation rates of cereals. New Phytol. 135: 613-61t9. CHAPTER 4: UNDERSTANDING YIELDS OF CORN (Zeamays) AND ITS RELATIONSHIPS WlTH PLANT EXTRACTABLE WATER AND SOIL PROPERTIES- 4-1BACKGROUND Agriculhual fields vary considerably in their soil properties, landscape features, and management histories. As a result, this variability has been shown to contribute to yield. Much of the variation in yield can be measured with current techology, but the roo t causes of this spatial variability are unexplained. This project attempted to assess the infiuence of vanability in soil structure and water content on the spatial variabiliv in y ield. It was hypothesîzed that the importance of soil structure to yield is related to the soil's ability to provide oxygen, water and support for the growth of roots. As such, in Our previous work soil structure was defined by properties such as soil resistance, air- filled porosity and matric potential. More specificdy, soil structure was defined by an upper limit and a lower limit of plant extractable water. The upper Limit was chosen as the lower value of wâter content-in which aeration to the roots becornes limiting, or when rapid drainage ceases. Aeration was considered to be limiting at an air-filled porosity of 0.1 cn$/cn13 (Grable and Sienier, 1968), and rapid drainage was considered to cease at field capacity (FC) at a water potential of -0.01 MPa (Hake et al. 1955). The lower limit values were chosen as the greater value of fhe water content below which water canno t be extracteci by plants (permanent wilting point or -1,5 MPa) found by Richards and Weaver (1944), or the water content at which mechanical irnpedance restricts root growth. Based on studies done by Taylor et ai., (1966) and Greacen (1986), a cone resistance of 2 MPa was used as the upper Mtof mechanical impedance. Analysis described in Chapter 3 showed that water contents measured during the growing season rarely surpassed the upper limits but often fell below both the lower limit of 2MPa soil resistance and the PWP. When these lïxnitïng water contents were compared with yield however, few significant relationships were found and it became evicient that measu res of hniting wa ter contents, as they were currently defined, were inadequate in explaining the vanability in yield. There have been studies showing that root penetration has occurred in soils ranging from 3 MPa (Laboski et al. 1998) to 5-7 MPa (Gerard et al., 1982) penetration resistance. In another study, Dexter (1987) suggested that critical root impedance was not static (i.e. 2MPa) but moved relative to the [natric poten tidl within the soil. There is also evidence showing that corn has the ability to extract soil water beyond the classicd limit of -1-5 MPa matric potential (Cabelgueme and Debaeke, 1998). Feddes et al. (1988) and Kay et al. (1999) attempted to define three critical water contents for transpiration and photosynthesis of corn: an upper litnit at which gas exchangr was reduced, a threshold limit below which rapid declines in gas exchange occured due to drought, and lower limît in which transpiration and ph~tos~vnthesis approached zero, due to drought. A conceptual illustration can be seen in Figure 4.1. Soii 'dater Content Figure 4.1. Conceptual model describing plant gas exchange as a function of soil water. Considering Our previous work it is easy to undentand how this working model might fit in with Our previous hypotheses. Seasonal water contents fallirig outside of the "aeration lirnit" or the "threshold Lirnit" would impact upon plant growth and ultirnately final yields. Again considering our previous work, we how that the majority of our water contents were found towards the dry limits. Therefore a definition of the "threshold hut" and a determination of how this limit varies with soil properties, would be great step in our understanding of how soii structure and water content rnight affect plant growth and yields. Ln their work however, Kay et al. (1999) found that defining the threshold limit across a range of soil properties was difficult. Also, other authors studying this concept have determined that defirüng the threshold Lùnit is dependent not only on soil properties but atso evaporative demand (Sadras and Milroy, 1996). Considering that it is unlikely that we wiil be able to use the threshold limit concept in helping us to understand yield variability. perhaps we can use the "lower liiiiit" concept. Contrary to the threshold limit results, Kay et al. (1999) found that the lower limit was highiy correlated with soi1 properties. In th& analysis of the lower limit they found that soi1 water content at which photosynthesis ceased (80,) was highly correlated with soil properties: 80, = -0.143 + O.ûû390+(% clay) + O.Oll48*(% OC) + O.l65*(%relative compac tion) (4-1) where ali statistical parameters were sigruficant to p<0.05, and r2 = 0.97 was found. They a Iso found thd t the parameter @O,,, dcrosç d range of soiis, was not equivalent to the critical points of -1.5MPa water potential or 2MPa penetration resistance. Therefore, use of this lower Limit parameter to determine new critical water potentials or soil resistance Mtsis udikely but conside~gits excellent correlation with soi1 properties, perhaps Equation 4.1 itself can be used as the lower limit of plant extractable water. The concept of the lower limit, here proposed as Oop, could be considered a quantifiable parameter in which to define the lower lirnit of plant extractable water by using the inherent soil propertîes such as texture, Bd and OC. The difference between the seasonal average water content (QS,,,) and 80, would then provide a measure of seasonal average plant extracta ble wa ter content (to be referred to as PEW,.,). The broad objective of this project was to nssess the influence of soi1 properties and soi1 water on the variability of yielcis in corn. The parameter PEW,,, is essentiaily a concept describing plant extractable soil water independent of soi1 properties and therefore PEW,.,should influence plant growth. Also, researd-i thus far has focused on the influence of these soil properties on soil water and how that in turn affects yields. Yet to be discussed is the direct rela tionship between other soi1 properties such as OC, %clay and relative compaction, and the variability of yields. An understanding of these rela tionships would also help in understanding the variabiiity of yields. The objectives of ttus study were to: (a) assess the irifluence of PEW,, as a measure of plant extractable water independent of soil properties, on the variability of yields of corn and, (b) to determine the direct relationships between yields and other soil properties such as OC, % clay and relative compaction, to better understand the scope of the relationships between the variability in soil properties, soil water and final yields of corn. 4-2 METHODS AND MATERIALS This study was conducted upon 6 farms during the 1998 growing season and 4 farms during the 1999 growing season. AU sites were located between Thamesville and Beeton, Ontario, Canada (Figure 4.2). AU farms were planted to corn (Zeamays) in the season of sampling. Tillage upon all farms was either conventional till or zero-tiU management. Figure 4.2 Map of sites in southem Ontario. To characterize each site, plots were selected on the basis of landscape position to àchieve variabili ty in y ield, seasonal wa ter content and soi1 properties. The experimental design of this project was a factorial experiment using a randomized complete block design with several replications, each with several plots divided by Iandscape position and 2 treatments: 150kg/ha N fertiiization and no N fertilization. Eight of the farms were each characterized by establishing 24 plots: 4 replicates, each with the 2 N treatrnents, and 3 Iandscape positions: upper slope, mid-slope and toe-siope positions. The remaidg sites were located at the Elora Research Station where each site was characterized by 30 plots: 3 replicates with 2 N treatrnents and 5 landscape positions (Upper slope, shoulder, mici-slope, Lower dope and toe-slope). For all farms, plots were approxinlately 5m long and 6 rows wide. At the start of each growing season, four sets of 30cm Time-Domain Reflectometry (TDR) probes were ïnstalled verticdy (15cm from the corn row) in each plot. Volumetric wa ter content was measured weekly, starting shortly after seedhg emergence and N fertilization- At the completion of each growing season, prior to harvest, 2 undisturbed cores (5cm diameter x 25cm height) were taken next to each set of TDR probes. Overaii, 8 cores were taken from each plot, four cores at 5-7.5cm depth and another four cores were taken at 20-22.5cm depth. In di, 2076 cores were collected. Each core was wrapped in cellophane and stored at 4OC untii used for analysis. l nunedia tely after core collection, a 6 metre length of corn row was hand harvested in each plot. The harvested corncobs were kiin dried for several weeks, sheiled and weighed to calculate hnal yields. Yields are expressed on a dry weight basis. Soi1 from each core was split into 2 parts; one part was sieved (2mm) and used for particle-size analysis; the O ther was ground and used for OC analysis. Particle size analysis was done using the hydronieter method and calibrated with the pipette method (Sheldrick and Wang, 1993). Organic carbon analysis was done using the LEC0 SC 444. Relative compaction (RC) was calculated using the equation: RC = bulk density/ Bdref (4-2) where Bdref = the reference bulk density. Reference b~& dertsity was cdculated from measurements of texture and OC using the pedotransfer function developed by Kay and To (2000): Bdref = 1.94 - 0.072*OC - 0.0066*(% day) - 0,82l*(OC/ % clay) (4-3) The lower limit of plant extractable water (€lap) was cdculated using Equation 4-1 - The parameter PE W,,,, was calculated as the average seasonai water content (O,,,) niinus Bu,- Regression analyses (SAS), hear and nonlinear, were used to evaiuate the reiationships between yield (+N)with PEW,,,, 80, and other soil properties. Evaluation of yields, seasonal water and soi1 properties was restricted to N fertilized treatments only. It was assumed that the yields measured within the +N treatments were not n utrient iirnited and the variation in yields was affected by only soil water and soil structural effects. 4.3 RESULTS AND DJSCUSSION Data collected from Our 12sites varied considerably in theïr yields, water contents and soi1 properties. A summary of OC, Bd and textural properties is shown in Table 4.1. In general, textural analysis of our plots showed that our 12 sites ranged from 0- 60.3% clay content and 3.2- 928% sand content- Organic carbon and Bd ranged from 0.20 - 5.88% and 0.89 - 2.02 g/cm3, respectively. A summary of yield data and soil water contents is shown in Table 4.2 In total, yield(+N) data ranged from approximately 1200 kg/ha to nearly 14000 kg/ ha, e,,.,, ranged hom 0.08 crn3/crn3 to 0.37 cm3/cm3, and PE W,,,, ranged fron-i -0.02 cm3/ cn13 to 0.28 cm3/ cm3. Unlike results hom the previous chapter, seasonal water contents rarely fell below the lower Mt 80,. Only the three Canagra sites showed any evidence of seasonal water contents falling below the lower Lilliit. Yield (+N) data was regressed against the two soi1 water parameters 8,,, and PEW,,,; results can be seen in Table 4.3 and Table 4.4, respectively. Common characteristics were identified among the 22 sites and sites were segregated according to these characteristics. Three sites (Elora no till1999, Denys and Newcombe) showed very little yield variabiiity across aii pLots. Of Our 12 sites, only these 3 showed standard cievia tions in yieId (+N treatntents only) of less than 1000 kg/ha. It was deterrnined that these 3 sites showed so Little variability in yield that signrficant correlation with soil and water characteristics would be difficult to establish. As a result these sites were eliminated from further analysis. An example of one of these sites can be seen in Figure 4.3. Table 4.1. Summary of soi1 properties for ail plots on eadn site (0-30cmdepth). Bulk Dençity Organic Fann: (dan3) Carbon(%b Sand(%) CIay(%) EC98: Elora 1998 Average: (conv. dl) St- Dev.: Minimum: Maximum: E98: Elora 1998 Average: (no till) St. Dev.: Muumum: Maximuni: EC99: Elora 1999 Average: (conv. till) St. Dev.: Minimum: Maximum: E99: Elora 1999 Average: (no till) St, Dev.: Minimum: Maximum: McCracken Average: (no îiü) St- Dev.: M inini uni : Miixin~uni: Pudoluiski Averclge: (conv. till) St, Dev.: Minimum: Maximum: CN: Canagra Average: North St- Dev.: (no till) Minimuni: Maximum: A verilce: St. Dsv.: Miiiini UL.: Maximuni: CC: c~~ri'lgr;~'Average: South St. Dev.: (no til) Minimum: Maximum: Denys Average: (no tîil) St. Dev.: Minimum : MdxÙIl unl: A vertige: SL. Drtv.: Miriin1uni : Maxim uni: Newconibe Average: (no tiU) St. Dev.: Miltimum: Maximum: Table 4.2. Statistical data for average 0,, PEW,,, and ha1yield data for ail ploîs. Avg- 0- Avg, OOp Avg, PEW- Final Yields Farm: (cd/an3) (cm3/cm3) (cm3/an3) &g/ha): EC98: Elora 1998 Mean: (conv. tili) Std. Dev.: Muumurn: Maximum: E98: Elori 1998 Mean: (no tu) Std. Dev.: Miium un1: Maxim um: EC99: Elora 1999 Mean: (conv. till) Std. Dev.: Minimum: Maximum: E99: Elora 1999 Mean: (no ta) Std. Dev.: Minimum: Maxiniuni: McCra~*ke 11 Mean: (no U) Std. Dev-: Miiùm un-i : Maximum: Podolinski Mean: (conv. di) Std. Dev.: MùUmum: Maximum: CN: Canagri Mean: North Std. Dev.: (no till) Mininiuni: M~ixin~uni: Mean: Std. Dev.: Minimum: Maximum: CC: Canagra Mean: South Std. Dev.: (no ta) Minimum: Maximuni: Denys Meiin: (LIUlill) Ski. Dev.: M üiini un1 : Maximum: Cameroii Mem: (no ta) Stci. Dev.: Minimum: Maxiniuni: Newcombe (no Mean: Std. Dev.: Minimum: Table 4.3, Results of regression analyses between yield (+N) and average measured seasonal water contents (84- Farm: Rem on Parameters: Prediction: EC98: Elora 1998 Yield (+N)= -9820 + 534&.w(8,,) Rz = 0.3% (conv. tiii) SSE= 289 x1W Yield (+N) = 9625.5t R?-= n/a 1 + exp(43.761$*(8,,- O-1263t)) SE= 229 x 107 E98: Elora 1998 Yield (+N) = 1a.6 + 32507.0$*(8,,) R? = 0.23 (no till) EC99: EIora 1999 (conv. till) E99-Elora 1999 Y ield (+N) = 10142O-t- 15436-Of(0,) (no till) Mchcken (no till) Y ield (+N) = 9437.2t + 9956.9t*(0,) R2 = 0.390 SSE = 1-28 x 201 YieId (+N) = 12639-7t R2 = n/a 1 + exp(-19.46*(8,, - 0.05)) SSE = 9.89 x l@ Y irld (+N) = 24407.0-f - 39127.0t*(8,,,) R'- = 03-11 CN: Canagra North Yield (+N) = 3911.8$ + 14806-CY(8,,) (no till) CS: Canagm North (conv. till) CC: Canagra South Yield (+N) = 2179.1 + 99858*(8,,) (no till) Denys (nu till) Canierux~(nu till) Yield (+N) = 16054.7t R= = n/a 1 + exp(-10.83*(8,, - 0.123$)) SSE = 8.60 x 1@ Newconihe (no till) Yield (+N) = 6846.6t + 6378.1'(0,) t = rcgrcssioti ~i~;nific-,.in~(p<~.U5), $ = regressioii sigiacant (p<0.10), all other parameter estimates Ge fourd not sig~iificant.R' vdues for non-linear regressions could not be deternuied. Con~parisonwas done using SSE. Table 4.4. Results of regression analyses between yield (+N) and average measured seasonal water contents (PEW-), Y EC98: Elora 1998 Yield (+N) = -1641.2 + IW70.V(PEW,,) R2 = 0.642 (conv. tiil) YieId (+N) = 10S17.3t R2 = n/a 1 + exp(49-9'( PEW,, - 0.069-f)) SE= 1.63 x 1W E98: Elorâ 19% (no till) ECw Wurct 1999 (conv. dl) E99: Bora 1999 (no tiU) McCracken (no till) Poddinski (cunv. tiil) CM Canûgra North Yield (+N) = 58û6.8t + 14113.(r( Pm,,) (no till) CS:Cariagra North (conv. tif 1) CC:Cariagrci Suuth Yield +N = 4826.7t - 5306.2*( PEW,,) (no lill) Denys (i~otill) Cameron (no till) Y ie1d (+N) = 4793.3t + 45576.Wt( PEW,,) RI = 0-628 SSE = 1.91 x 107 Yield (+N) = 132553t 1t exp(-29.7r(PEW,, - 0.072t)) Rz = n/a SSE = 1.30~107 Newconibt, (no till) t = regessioit sig~iificmt(p Figure 4.3. Example of a site with little yield variation (Denys site). One other, the EIora no ta1998 site, was ais0 elirninated from further analysis. On thïs site a frost event occurred early in the growing season that affected many of the seedhgs in the lower landscape positions and had an indeterminaie effect on yields. Of the eight remaining sites, homajor trends were observed; one group in which yields were found to be signrficantly correlated with PEW,,,, and another group in which yields were not. Of the 8 sites, the 3 Canagra sites (CN, CS, and CC) were the 3 that did not show significant correlations with PEWWs. Upon further analysis all three sites also showed unusualiy low PEW,, values, ranging from -0.02 to +0.10 cm3/cm3. Therefore, soi1 water contents on these sites persisted at or dropped below the @op throughout the measurernent period. It is possible that no correlations were found between yields and PEW,,, on these sites because plant extractable water was so low. The five remaining sites (Elora conv. till1998, Elora conv. till1999, McCracken, Podolinski, and Canieron) were those in which signihcant correlations were found between yield and PE W,,,. ln general, the relationship was found to be positive, where yields increased with increased plant extractable water. The relationship between yield and PEW, was not strictly hear however, where the relationship in the McCracken, Cameron and the Elora conv. till1998 data showed evidence of a logistic pattern- Nonlinear regression analysis was performed on these sites but only the Cameron farm converged to determine nonlinear parameters significant to the p4I.05 leveL Nonlinear regression analyses of these 3 sites can also be seen in Table 4.4. Overall, nonlinear regression converged for all3 sites and resuited in reductions in the nim of squared errors when compared with their hear equivalents, but regression parameters were not always fomd to be significantly different than zero for the McCracken and Elora conv. 1998 sites. Plots of this nonlinear behaviour in all three sites cm be seen in Figure 4.4. From these plots a "threshold linif' (discussed in Figure 4.1) of approxïmately 0.10-0.15 cm3/cm3 water above the lower lirnit €Iop, can be seen. Figure 4.4. Examples of norhear behaviour between yield and PEW,,,. A site of special note was the Podohski site, a predorninantly day site, in which significant negative correlations were found between yield and 8, (p<0.05), and between yield and PEW, (p<0.10) (Figure 4.5a). Contrary to the others, on this site it appearç that the areas of high yieIds were liriked to areas with low seasonal water contents. The critical difference in this analysis may be that the Podohski site has soils of high clay (average 44%clay). Analysis of the Podolinski site show that seasonal water contents fiequently surpassed the critical Lunit of 10%aeration porosity. Aeration has been cited to be criticaiiy ümiting to plant growth at an air-med porosity of 0.10 cm3/cm3 (Grable and Siemer, 1968) and could explain the negative correlation found between yield and PEW- for this site. Yield was found to be negatively correlated with the frequency at which seasonal water contents surpassed the 10% air-med porosity lin-iit (Figure 4.5b). Figure 4.5a, b. Nega tive correla tions found behveen yields and soü water measures (Podolinski site). Yield data was also regressed against three other soi1 properties: OC, %dayand K.Of these soi1 pro perties, % clay and RC showed relatively poor correlations. Clay content, when correla ted with yields (+N),was found to be signlficant (p<0.10) in only one site (CçCanagra). The McCracken and the Cameron sites however, did show 94 evidence of nonhear behaviour but the nonlinear regression parameters were found to be not sigruficant. In general, because clay content was found to be signihcant in only a few sites and these correlations were poor, it is unlikely that these correIations will improve our understanding of the role of clay content upon the variations in yields. Relative compaction was also correlated with yields (+N), and was found to be significant (p~0.10)in 6 of our 12 sites. The relationships found however, were contradictory. For example, the Elora no till1999 site showed a sigruficant (pC0.05) negative correlation between y ields and relative compaction (Figure 4.6a). This data was consistent with studies done by Carter (1990) that çuggested that yields of cereals declined when relative compaction was greater ihan 0.85-0.90. In the CS-Canagra data however, yields were found to be signihcantly (p<0.05) positively correlated with rela rive compaction (Figure 4.6b). Ln general, it is unlikely that relative compaction of the soi1 played a major role in deterrnining variations in yields. I *.= a> ,.* b) -1. O* zsoooi--1 m 54000; 0 o!3000 t ZOOO; Io00 - l 07- - --y,71 0 1 l 0.85 0.90 0.95 1.O0 1.05 0.85 0.90 0.45 1.00 1.05 RelativeCarpadim Retati\RCorrpadion Figure 4.6a,b. Different correlations between yield and relative compaction: Elora no till1999 (a), CS-Canagra (b). Of the three so il properties regressed with yield data, OC showed the best correlations. Results af these correlations can be seen in Table 4.5. Overall, 7 of our 12 sites showed sigiuhcant iinear correlations with OC Another site, the McCracken site, did not show a significant linear relationship, but did show a clear non-linear rela tionship . Non-linear regression of this reiationship however, did not generate significant (p<0.10) parameter estimates. A plot of the McCracken yield vs. OC relationship cari be seen in Figure 4.7. It is interesting to note however, that there were similar relationships seen between the OC analysis and the PEW,,, analysis. The three sites that were elimiriated from the PEW,, analysis (Elora no tiU 1999, Denys and Newcombe) because of small standard deviations in yields were &O found to be not si&nificantin the OC analysis. W hile a significant correla tion w as seen between yield and OC in the Elora no till1998 site, it is stiii unknown wha t affect the frost damage had on yields and therefore thiç site was agam elinunnted fr0111 further analysis. Of the 8 sites remaining, aU 8 showed signhcant relationship with PEW,,,,. Their relationships with OC however, varied. 0.0 1.0 2.0 3.0 4.0 5.0 6.0 Organic Carbon content (%) Figure 4.7. Nonlinear behaviour of yield vs- OC (McCracken site). Table 4.5. Results of regression analyses be tween yield (+N) and organic carbon (OC), >Farm: EC98: Bora 1998 YieId (+N) = 4758.1-t + 10253*(0C) (conv. till) E98: Elora 1998 Y ield (+N) = 3850.2t + 1746.8r(OC) R2 = 0.357 (no till) EC99: Elora 1999 Yielci (+N) = 46829-f + 150LL5r(OC) R2 = 0.461 (conv. till) SE= 1.35 x lW Yield (+IV) = 8975.7t Rz = n/a 1 + exp(-2388t'(OC- 1.06t)) SE= 8.63 x 1CF EW-Elo ra 1999 Yield (+N) = 52T5.2t + 594T(OC) (no tr'll) McCracken (no till) Yield (+N) = 1llll.û-t + 4199(0C) R? = 0,176 SE= 1.72 x 107 Yield (+N) = 12236.6t R2 = n/a 1 + exp(-3.77$*(OC - 0.09)) SSE = 5.32 x 108 Podolinski (conv. till) Yield (+N) = 6827.w + 1859.lt*(OC) Rz = 0.423 CN: Canagra North Yield (+N) = 6û85.q- 4 156.0*(UC) (no tiil) rS: Cànagra North Yield (+N) = 3038.6-f + 16243y(OC) (cunv- till) CC: Canagr-Suu th YielJ (+N) = 1109.1 + 1533.3r(OC) (no till) Denys (no tiII) Yieid (+NI= 8636.2t - W.2*(OC) Cmeron (no tilI) YieIci (+N)= 5539.6f- + 3366.5y(OC) Rz = 0.665 SSE = 1.72~107 Yield (+N) = 13ZZ8t Rz = n/a 1 + exp(-220t*(OC- 0.731t)) SSE = 1.02 x 107 Nswcoiilbe (no till) YieId (+N) = 73û6.2t + 750-8*(CC) t = regression sibdcmt (p (the three Canagra sites), two sites (CC-Canagra and CS-Canagra) did show si@cant cordations of yield with OC. These three Canagra sites were sites in which PEWS- values were found to be extremely low. This may have affected the yield vs. PEWea relationship, but the fact that sigruficant relationships between yield and OC were found on two of these sites leads to the hypothesis that on these 2 sites yields were sigüfiicantly effected by OC in a manner unrelated to water extrackibility. Plots of yield with PEW, and OC, for the (23-Canagra site can be seen in Figure 4.8. -- Figure 4.8. Plots of yieid with PEWseJs and OC, for the CS-Canagra site. Of the five sites in which significant correlations were found between yield and PEW,,, (Elora conv. till1998, Elora conv. till 1999, McCracken, Podohski and Cameron), three sites were also signhcantly correlated with OC. The McCracken site, with its evident non-linear relationship could also be included. ïherefore, four of tthe five sites (Elora conv. tiii 1999, McCracken, Podolinski and Cameron) can be said tco also show a relationship with OC. Also much üke the relationships found with PEW,., the relationship between yield and OC was found to be positive. Therefore, high yields were in general linked to areas of high OC and soilç with high plant extractable water. This can be seen in an exarnple of the Carneron site where positive relationship can be clearly shown between PEW,,, and OC (Figure 4.9). I 0.00 ; 1 0.0 1-0 2.0 3.0 Organic carbon content (%) Figure 4.9. Example of the relationship between PEW,, and OC (Carneron site). Again, the site of special note was the Podoltriski site, the predominantiy clay site in which significant negative correlations were found between yield and PEW,,. Coupled with this hding was a sipificmt positive correlation between yield and OC (Figure 4.10a). Contrary to the relationships seen in the O ther sites, the Podolinski site indicates that areas of high yields were linked to areas of high OC but lower plmt extractable water contents. Again, the critical difference in this andysis may be that the Podolinski site has soils of high clay. lt has been seen that the Podohski site experienced several occurrences of water contents surpassing the critical Limit of 10% aera tion porosity and that yields were found to be negatively correlated with the Frequency of seasonal water contents surpassing this i.i..miL Therefore on the Podolinski site, it is tikely that high OC is linked to areas of lower water contents and lower occurences of seasonal water contents surpassing the 10% aeration porosity limit This can be seen in Figure 4.10b, where the frequency at which seasonal water surpassed the 10%aeration porosity limit was found to be negatively correlated with OC. Figure 4.10. Behaviour of yield, OC and soi1 water contents on the Podolinski site. Therefore, of the original hypotheses, yieIds do show some relationship with PEWsepson some of our sites, but the anticipated irnprovements in predictions when compared to the independent variable of O,,, ,were not seen. However, perhaps the most significant result of our analyses may be that OC was found to be a sigruhcant indicaior of ideal growth conditions under ds; water limiting conditions as well as wet, aeration Limiting conditions. In essence, on many of our sites OC was ciosely linked to those areas with the "least iinuting" water regimes during the growing season. Yet overall, for many of our sites it is still evident that much of the variability in yields is not explained by water parameters or soi1 properties. Could other factors influence the variability in yields? Certainly nutnents, insects, disease or clirnate rnay have played a role- No insect or disease damage was evident however, and presumably clirna te (temperature, sunlight, etc.) was unifom across al1 plots on a site. Analyses thus far have also only included +N treatments and these plots were assumed not to be nitrogen limited. Although other nutrients were expected to be present at adequate levels; this expectation was not confinned. Nutrient deficiencies by thernselves however, are unlikely to explain why so much of the variation in yields is yet unknown. Another drawback of our analyses may be that our water and soil analyses extended over only the 0-30cm depth- While the majoriq of plant roofs are Çound within the 0-30cm depth it is possible that variation in water content and OC below 30cm could improve predictions of variation in yields. We may also lack clear and accurate iimits describing limiting conditions for plant growth. As was seen in Figure 4.5b, yields showed a good relationship with the frequency in which seasonal wa ter contents surpassed the 10%air-filled porosiv limit. 'What our knowledge lacks however, is a sirnilar lower limit which we can use sin-iultaneously. Our current lower Linut of 80, is inadequate for this purpose because it is theoretically the " basemen t" of Liniiting plant conditions. What is needed is a threshold in which linxiting plant conditions begin. From Figure 4.4, our data indicated a " threshold lirrùt" of approximately 0.10-0.15 cm3/cm3 water above the lower Mt. However, this value was a crude estimate based on visual examination of the data. Better data and an understanding of what determines how this threshold Limit varies could grea tly in~proveour abilitv to predict variations in yields. ln general, it is theorized that the relationship of yield with water is dependent on extractable water, in a form similar to that shown in Figure 4.11. This conceptual mode1 is similar to that proposed by Feddes et al. (1988) as seen in Figure 4.1. It is theorized that those soil/ precipitation/ landscape position conditions that result in PE W,,..,, falling w i thin the Type 1 range will show little or no relationship between yield and PEW,,, because extractable wa ter is extremely limiting (i.e. the 3 Canagra sites). Those soil/ precipitation,' landscape position conditions that fall within Type II wili show a positive relationship between yield and PEW, (ie. the 4 sites Elora conv. tiU 1998, EIora conv- till 1999, McCracken and Cameron), and the soil/ precipitation/ landscape position conditions which have large ranges in PEW- will show logistic relationships and span both Type II and III (the McCracken and Cameron sites). Those soil/ precipitation/ Iandscape position conditions that experience adequate extractable water throughout the growing season will fall solely in Type III and wiU show Little or no relationship between yield and PEW,.. The 3 sites eliminated hom further analysis, the Elora no till1999, Denys and Newcombe sites, which showed good yields but little variation, could be examples of Type LI1 growth. Findy, it is hypothesized that for those soils in which PEW,, was at times hi& enough to limit aeration, Type IV growth would be exhibited (the Podoiinski site). Plant ExtractableWater Figure 4.11. Conceptual model descnbing yields as a funcnction of plant extractable water. From our data however, it is uncertain as to where or how to demark the bo undaries within this concep tua1 model. From our introduction, determining the point in which water stress becomes evident in photosynthesis ûr transpiration can depend on climate conditions or plant cultivar. For example, the boundaries between Type III and IV would be highly dependent on the specific plant adaptations to waterlogging. Ako, yield could be dependent on the tiniing of the Lùnitations in extractable water. For example, it is conceivable that plants experïencing low extractable water during silking would redtin a greater loss of yield than at any other stage of devdopment From our data, this temporal effect of plant extractable water is not testable. In general, our data showed strong temporal stability of soi1 water contents withui spatial patterns. This cm be seen in Figure 4.12, where the pattern of water content across Iandscape positions remairis stable throughout the growing season. As Iong as this pattern remairis relatively intact, regression of yield values with any single time perïod (i-e. water content pattern at siiking) is essentially no dïfferent to the regression of yield values with the average sedsonal water content during growing season. However, this again leads to the importance of a clear deiuarkation of a "threshold" limit. With a clear threshold bit, the temporal effects of plant extractable water on yïelds codd be tested. Water contents found to faU below this iimït before, du~gand after siLking could be compared to yield values and used to determine the influence of temporal effects of water on the variability in y ields. I Julian Day Figure 4.12. Example of the temporal stability of extractable water across spatial patterns (McCracken site). 4-4 CONCLUSION Phtextractable water, expressed by PEW5faSIwas found to significantly correlate with yields on many of our sites but overd, much of the variability in yields remained unexplained. Of signihcant note however, organic carbon was found to be well correlated with yields. Organic carbon was found to be linked to increased plant extractable water under drought conditions as well as being linked to better aeration conditions under wet conditions. In general, organic carbon was found to be highly iinked to areas of "Ieast limiting" water conditions and in many cases was found to be the best predictor of yield variation compared to all other independent variables attemp ted- 4.5 REFERENCES Cabeigueme, M., Debaeke, P. 1998. Experïmental determiation and modehg of the soil water extraction capacities of crops of maize, sunfïower, soya bean, sorgfium and wheat. Plant and Soil. 202175-192 Carter, M.R. 1990. Relative measures of soil bulk derisity to characterize compaction in mage studies on fine sandy loarns. Can. J. Soil Sci. 70: 425-433. Dexter, A.R. 1987. Mechanics of root growth. Plant and SoiI. 98: 303-312- Feddes, R.A., Kabat, P., Van Bakel, P.J.T., Bronswijk, J-J-B., HaIbertçma, J. 1988. Modelling soi1 water dynamics in the unsaturated zone - State of the art Journal of Hydrology. 100: 69-111. Grable, A.R., Siemer, E.G. 1968. Effects of bulk density, aggregate size, and soi1 water suction on oxygen diffusion, redox po tential and elongation of corn roots. Soil Sci. Soc- Am. Proc. 32180-186. Gerard, C.J., Sexton, P., Shaw, G- 1982. Physicd factors irduencing soi1 strength and root growth. Agronomy Journal. 74: 875-879. Greacen, E. L. 1986. Root response to soil mechanical properties. Trans. 23th Congress In tern. Soc. Soil Sci., Harnburg, Germany. 5:20-47. Haise, H.R. Haas, H.J., Jensen, LX. 1955. Soii moisture studies of some Great Plain soils: II. Field capacity as related to 1/3-atmosphere percentage and "minimum point" as related to 15 and 26- atmosphere percentages. Soil Sci. Soc. Am. Proc. 34:20-25. Kay, B.D., Tollenaar, M., Drury, C.F., Yirig, J., Chromiak, C., Zhang, T. 1999. Increasing ni trogen use efficiency in corn production systems: quantifying effects of quality of soi1 structure and water regimes. Final Report to Ontario Research Enhancement Program, Agriculture and Agri-Food Canada. Kay, B.D., To, J. 2000- Use of data on soi1 structure and soiI water content to interpret yield variation within fields. Final Report to Ontario Corn Producers Association. Laboski, CA.M., Dowdy, R.H., Aharas, R-R., Lamb J.A. 1998. Soil strength and water content influences on corn root distribution in a sandy soil. Plant and Soil. 203: 239- 248. Richards, L. A., W eaver, L.R- 1944. Fifteen atmosphere percentage as related to the permanent wiltïng point Soil Sci. 56:331-339. Sadras, V-O. and MiLroy, S.P. 1996. Soil-water thresholds for the responses of leaf expansion and gas exchange: A review. Field Crops Reseasrch. 47: 253-266. Sheldrick, B.H., Wang, C. 1993-Particle Size Distribution. h: Soil Sampling and Methods of Analysis, M.R. Carter, Ed. PP: 499-511.Canadian Society of Soil Science. Lewis Pubiishers. Taylor, H.M., Roberson, G.M., Parker, Jr., J.J. 1966. Soil strength root penetration relations for medium to coarse textured soil materials. Soil Sci. 10218-22. CHAPTER 5: UNDERSTANDING THE VARLABILITY OF YELD RESPONSE OF CORN TO NITROGEN FERTILIZER ACROSS RANGES OF WATER AND SOIL CHARACTERISTICS 5.1 BACKGROUND Agridtural fields Vary considerably in their soi1 properties, landscape katures, and management histories. This variability has been shown to contribute to variation in y ield. Colvin et al. (1996) described the yield patterns for corn and soybeans in rotation after six consecu tive years within a single Field. They found that certain locations within the field had consistently high, consistently low, or erratic yields when compared to whole field averages. Understanding the root causes of these yieId variations wouid give us important tools in leanùng how to manage our land more efficiently . Site specific farniing is such a management stra tegy and is dehed as an agricultural system ~iesignedto iden tify, analyze and manage soi1 spatial and temporal variability across a field for the purpose of increasing sustainability and profit. Soi1 structure and water regime are obvious factors influencing yield and therefore an understanding of how they interact with yields will bring us closer to efficient site specific farmuig. From our previous work it was determined that the concepts of the permanent wifting point (PWP), available water holding capacity (AWC) and other soi1 water limits associated with the least lirniting water range (LLWR) proposed by Letey, (1985) and Da Silva and Kay (1997), were not adequate in explaining variations in yields in Our data. From another study, Kay et al. (1999) found that photosynthesis in plants stopped as the water content ciecreased to a lower linzit (€Iop) and that this lower iimit was highly correlated with organic carbon (OC), %clayand relative compaction (RC). This limit was also found to be unrelated to those limïts proposed in the LLWR. Using the concept of BO,,, it was theorized that the average seasonal soi1 water contents measured above the lower limit was a measure of plant extractable water (PEW,,,) throughout the growirig season. From our analyses, it was found that yield in the N fertïiîzed treatrnent, yield +N, (assumed to be no t nutnent Lirnited) was sigruhcantly correlated with the average seasonal soi1 water contents (84and PEW,,, in many of our sites. Yield +N was also found to be related to OC- OveraU it was seen fhat yields +N were sigdicantly influenced by this new description of extractable water and tha t both yields and optimal water contents for plant growth were Luiked with OC. If PEW,, and OC were closely Iinked with yields +N, what would their relationships be with yields under unfertilized conditions? For instance, plants grown in soils with high OC may experience good amounts of extractable water and experience Little N Limitations due to N mineralization from the OC. Standard rates of N application in such locations wodd therefore be inefficient. Considering inorganic nitrogen fertilizer is an essential component in the production of corn and can make up > 20% of operating expenses, understanding nitrogen use efficiency could have major implications for management and profitability of a farm. Understanding how yield response to fertilizer varies across sod characteristics may help us to understand what factors influence yield response and dtimately how we can manage accordingly. The objectives of this study were: (a) to determine if the response in yields of grain corn to an application of 150 kg N/ha varied with PEWsa, and OC, and @) to identify the implications for idenhfying N management zones with a field. 5.2 METHODS AND MATEMALS This study was conducted upon 6 faxms during the 1998 growing season and 4 farms during the 1999 growing season. Ail sites were located between Thamesville and Beeton, Ontario, Canada (Figure 5.1). AU famis were planted to corn (Zeamays) in the season of sampluig. TiUage upon all farrns was either conventional tili or zero-till management. Figure 5.1. Map of sites in southern Ontario. To characterize each site, plots were located to achieve variability in yield, seasonal water content and soi1 propertïes. To achieïe this plots were selected on the basis of landscape position. The experimental design of thiç project was a factorial experïment using randomized complete block design with several replications, each with several plots divided by landscape position and 2 treatments: 150kg/ha N fertilization and no N fertilization. Eigh t of the farms were each characterized by establishing 24 plots: 4 replicates, each with the 2 N treatments, and 3 Iandçcape positions: upper slope, mid-dope and toe-slope positions. The remaining sites were located at the Elora Research Station where each site was characterized by 30 plots: 3 replicates with 2 N treatrnents and 5 iandscape positions (Upper slope, shoulder, mid- slope, lower slope and toe-slope). For al1 farms, plots were approximately 5m long and 6 rows wide, At the start of each growing season, four sets of 30cm Time-Domain Reflectometry UDR) probes were installed vertically (15cm from the corn row) in each plot. Volumetric water content was measured weekly, starting shortly after seedling ernergence and N fertilization. At the completion of each growing season, pnor to harvest, 2 undisturbed cores (5cm diameter x 2.5crn height) were taken next to each set of TDR probes. Overall, S cores were taken from each plot, four cores at 5-7.5cm depth and another four cores were taken at 20-225cm depth. In all, 2076 cores were collected. Each core was wrapped in cellophane and stored at 4OC until used for analysis- lnunediately after core collection, a 6 rnetre length of corn row was hand harvested in each plot. The harvested corncobs were kiln dned for several weeks, shelled and weighed to calculate fuial yields. Yields are expressed on a dry weight basis. Soi1 from each core was split into 2 parts; one part was sieved (a)and used for particle-size analysis; the other was ground and used for OC analysiç. Particle size analysis was done using the hydron-ieter rnethod and calibrated with the pipette method 0 (Sheldrick and Wang, 1993). Organic carbon anaiysis was done uçing the LEC0 SC 444- Relative compaction (RC), the lower liWt of extractable water (00,) and the average plant extractable water during the growing season PEW,, was calculated using the same methods as Chapter 4. 5-3 RESULTS AND DISCUSSION Analysis of variance was performed on Our 12 sites to determine the effect of N fertilizer treatment on yields (Table 5.1). Of the 12 sites, 8 sites (Elora conv. tiU1998, Elora no till1998, Elora conv. tiii 1999, Elora no f5.ü1999, Cç-Canagra, CN-Canagra, CC- Canagra and Newcombe) did not show significant N treatment effectç on yields. Many of the 12 sites did however, show si@cant location effects although these effects were inconsistent across sites (e-g-Figure 5.2a,b)- Figure 5.2 ExampIes of differential location effects on yields: (a) CC-Canagra no till 1998, (b) EIora conv. tiii 1999. Regression analyses between yieids and the independent variables of e,,,,, PEW,,, and OC were also performed on the 12 sites. Results of these analyses can be seen in Appendix 5.1. Of the eight sites that did not show significant N fertiiizer treatment effects, analyses showed that six sites (Elora no tiii 1998, Elora no till1999, CN-Canagra, CS- Canagra, CC-Canagra and Newcombe) did show significant correlations between yield in the ON treatment and one or more of the soi1 characterstics es,, PEW,,,, and OC. When compared with the same +N treatment analyses, simiIar relationships were seen in aii eight sites. Supporting the ANOVA analysis, no evident yield response to N was seen between the two treatrnents in the regression analyses and the yield response to N was relatively uniform across the ranges of the independent variables. An example can be seen in Figure 5.3. In general, it was evident that for many of these 8 sites variability in yields (+N and ON) can be attributed to varying soil properties but fertiLizer N was not a signihcant factor. Considering management costs, the applied N fertilizer on these sites, during those particular growing seasons, showed little benefit. Because no significant treaûnent or treatrnent/soil propeq interaction effects could be found on these sites no further analysis of yield response was undertaken. I I j 0 +N ~reatrnent; 7000 ; I a ON Treatment 1 *O 1000 j O ! O. 0 1 .O 2.0 3-0 4.0 Organic Carbon content (%) Figure 5.3. CC-Canagra (no till) 1998 site. Evident OC effect upon yield (+N and ON) but no statisticdy significant effect of +N treatment Results of the ANOVA show that only 4 sites, the McCracken, Podolinski, Denys and Cameron farms, showed a significant N fertilizer effect on yield. For these 4 sites, yield in the ON trea tnient was regressed with the major soil properties 8,PEW,, and OC, and compared with the correlations found in the yield +N data. Analyses of the correla tions of yield +N and ON revealed 3 different scenaxios. The site with the simplest explanation, the Deny's site, showed no sipificant correlations between yield (+N or ON) and the 3 regession parameters (O,, PEW, and OC) but did show significant yield response to N fertdizer. The yield response however, varied by less than lûûû kg/ha or Il% of the maximum. A plot of yieid +N and ON, across a range in OC can be seen in Figure 5.4. Plots of yields with the 2 other parame ters showed similar results. 0.0 1-0 2.0 3,O Organic Carbon content (%) Figure 5.4. Denys site. No evident OC effect upon yields but statistically significan t N fertilizer effect. Dissirnilar to the Denys site are both the McCracken and Carneron sites in which a signïfïcant fertiiizer effect was found but significant correlations between yield (+N and ON) and e,,, PEW,,, and OC were also found. Also evident in the statistical correlations are differential behaviours between yield +N and yield ON across the ranges of soi1 characteristics. The influence of OC on yields is illustrated in Figure 5.5 for the McCracken site. The influence of PEW,.,, on yields in both N treatments (Figure 5.6) was similar to that of OC. Water and organic carbon were also closely linked with slope location on this site, where greater OC and larger water contents were found in the depressional areas and smaller values in the upper slopes. Table 5-1-ANOVA tables of location and fertilizer effects for each site- Elora (conv. till) 1998 -ss: MSE: F-test Faitical TOkd lM1726863 Replication 1178133.7 589066.8 0.4776 355 Treatznents 8W93562.0 Location 785606953 19640173.8 15.9238' 293 Fertilizer 10720 1.5 1072015 0.0869 4.41 Location'Fertilizer 2 L S65.2 5314163 0.4309 293 Error 22200990.6 1233388.4 Elora (no till) 1998 SS: -MSE: F-test Fuitical Tota1 40785751 -6 Replication '1 537727-4 768863.7 0.5385 3.55 Treatrnents 135467338 Locrlti~i~ 585ü898.1 1464724.5 2.0258 393 Fwiilizc~r 21~11bN.3 20616-49.5 1.4439 4.41 Lricir~ii)ri'Fcr~ili/.~'r 5~20175.1 14V6543.8 0-9851 393 &or 25701 301 -4 1127850.1 Elora (conv- tül) 1999 ÇÇ: -MSE: F-tes t Fmtical To ta1 36791 069.0 Elora (no tiU) 1999 ÇS: MSE: F-tes t Fmtical Totd 243'72273-4 McGadcen (no till) 1998 ÇÇ: MSE: F-test Fcritical Tota1 2235841473 Replication 8335661.7 2778553.9 12îi8 3-29 Treatmen ts 181136327.6 Location 960 17%3 480087&l.2 21.110r 3.68 Fertilizer 68351 250.2 68351250.2 30.0558' 4.54 Location'Fertifizer 16767509-1 83a3751.5 3.6866' 3.68 Error 3-i 112~58.0 W4143.9 Podolinslcï (conv, till) 19% ÇS: MSE: F-test Fcritical Tota1 1863~~367.1 RepLication 4 1531207.4 13813735.8 5.4938' 3.20 Treatnwnts 107193777.0 Location 1252178.2 626089.1 02485 3.68 FertiLizer 101 129632.9 1041296329 413231' 4.54 Loca tio n*FertiliLer 181 1965.8 9059829 03595 3.68 Error 377-7 25 19892.2 CN-Canagra (no till) 1998 -SS: MSE: F-test Fcritical Totd 9021 1726.5 bplic-dtion I4069296.1 46897654 L .O553 3.29 Trwtme LILS w ~85.t) ~osdtion 28M-L90-1 1432245.1 03223 3.68 Fertiiizer 5830 108.8 5830108.8 13119 4-54 Losatio n*Fertilizer 7894S6.8 3942343.4 0.0889 3.68 Error 66633144.7 44.138763 CC-Canava (no till) 1998 SS: MSE: F-test Fcritical TV td 4 l86-l6X1 r\eplicdtiori 68 1 1796.7 2270598.9 33547' 3.29 Treatnients 2-1900200.0 Location 24 56760 1.2 12283800.6 18.1486* 3.68 Fertilizr r 174 1.6 1741.6 0.0026 4-51 Loca tio n'Fertilizer 330857.2 165428.6 U.2444 3.68 Error 10 152677.4 67W5.2 MSE: Replication 1631376.1 543792.0 0.7306 3.29 Treatments 1853429'7.9 Location 14875581.9 7437790.9 9.9925' 3.68 FertiLizer 31424823 31424823 4.22i8 4% Loca tion*Fer tilizer 516233.7 258216.9 03468 3.68 Error L 1 lmû7.8 74EM05 - -- - - Denys (no till) 1999 SS: MSE: F-test Fmtical Total 16395619.5 Replication 44256 1.9 147520.6 0.2542 3.29 Treatments 72489121 Location 1 133999.2 578499.6 0.9969 3.68 Fertiluer 5613113.0 5613113.0 9.6732' 4.54 LOC~tion*fertilizer 478s00.0 239400.0 0.4 126 3.68 Error 87W145.5 580276.4 Cameron (no till) 1999 SS: MSEI F-test Fuitical Tota1 939G-9%9 Replica tion 7795894.5 2598631.5 LT~~O 3.29 Treatmeiits 71769689.4 Location 472237533 23611876.7 24.6330' 3.68 Fertilizer 243%8653 243968653 25-45-19' 4.54 hciitiori'Fcrtiiizer 149070.8 7.15354 0.0778 3.68 Errc)r 1 -13782 1-1-11 9585i7.6 P Newcombe (no tiü) 1999 -SS: MSE: F-test Fmtical Tota1 18869 135.6 r\epLication 746771 4.2 2489238.1 1.0 133' 3.29 Treatmeiits 3128391.2 Location 5131 1.3 25635.8 0.0465 3.68 Fcrtiiiziv- 21 109-i8.-1 2110948.4 3.8274 4-51 Loc~~~i~~~*F~r~iiizer%hl313 483û65.6 0.6759 3-68 Err ur 8273030.2 33 15353 This is consistent with the ANOVA analysis of the McCrracken site where a significant fertilizer and location interaction was found. On the McCracken site it was evident that yield response to fertilizer N was greatest in those areas of low extractable water and low OC. The data indicate that beyond 1.5-2% OC, the yield response to N was consistent and low. This site may be a good candidate far variable rate fertilizer application and OC could be used as an indicator for detennining management strategy. Consideration of yield response must also account for the fact that only one N treatment was analyzed in this study. Perhaps other N treatrnents (iess than or greater than 150 kg N/ ha) would show different results. +N Treatment I Organic Carbon conternt (%) Figure 5.5. Yield +N and ON across a range in OC (McCracken site). ,.L ON Treatme 0.00 0-05 0.10 0.15 0.20 0.25 0.30 PEW,,,, (cm31cm3) -. ------Figure 5.6. Yield +N and ON across a range ~EW,, (McCracken site). Contrary to the McCracken data, analysis of the correlations between yields and OC on the Carneron site showed parallel relationships (no statistically significant interaction) between yield (+N and ON) and OC (Figure 5.7). Of note however, is the fact that the Carneron site did not have as wide a range in OC as the McCracken site. Perha ps if the range in OC contents on the Cameron site had been greater a sbonger interaction would have been observed. The Cameron site also showed significant yield response and yield response interaction with N treatment across a range of water contents. From the plot of yield +N and ON across a range in PEW,., (Figure 5.8) there seems to a critical water content (a p proxuiiately PEW,,,, = 0.12 cm3/crn3) below which yield deches. Upon further maiysis it is eviden t tha t the McCracken site also exhibits this behaviour. in both sites however, yield +N did not seem to exhibit as large a yield reduction at the lower water contents. It is unknown why yields in the +N treatments did not also exhibit this plant extractable water Limitation. A hypothesis for this re-enilt may be that in these areas of low OC and lower seasonai water, less N was mineralized and therefore the yields in the ON treahnents were profo-mdly affected by low water, as well as low N availability. In contrast, the +N treatments suffered due to low extractable water but did not suffer as greatly becauçe of inorganic N inputs. +N Treatment Organic Carbon content (%) Figure 5.7. Yield +N and ON across a range of OC (Cameron site). -Isooo +N Treatment .K.* - /. G ON Treatrnent Figure S.S. Yield +N and ON across a range of PEW,,, (Cameron site). The final site is the Podolinski farm. From the previous chapter, it was determineci that high yields on this site were linked to high OC and low soil water contents. Soils with low OC contents experienced high water contents that may have induced aeration limitations to the plants. Correlations between yield ON and OC for this site showed a similar relationship when compared to yield +N (Figure 5.9). A yield response interaction with OC was seen but was not found to be significant (pi0.10). This is consistent with the ANOVA resdts that showed no significant interaction between treatment and location. The range in OC for this site however, was between 1.4 - 3.3%. Perhaps if the range in OC for this site spanned OC contents Lower thm 1.4%, a greater yield response interaction may have been seen. From ouprevious chapter, regressions of yields +N vs. L,and PEW,, for the Podolinski site showed significant negative correlations. These relationships were attributed to the fact that our data showed seasonal water contents faUuig above the 10% air-filled porosity Mt.in contrast however, regession of yields ON showed no significant correlations with either 8,, or PEW,.. However, when yields ON were regressed agains t the frequency of seasonal water contents falling above the 10% air- fiiied porosity Limit, a significant negative trend was seen (Figure 5.10). This again supports some of our previous work indicating that definition of criticdy limiting plant conditions are crucial in Our understanding of water, soi1 and plant relationships. +N Treatment + Organic Carbon Content (%) Figure 5.9. Yield +N and ON across a range of OC (PodoLinski site). 121 2000 O! r 1 t 0.0% 2O.O0h 40.0% 60.0% 80.0% Freq, of Seasonal Water Contents Measured Above 10% air-filled porosity (%) Figure 5.10. Plot of yields in the ON treatment and the frequency of seasonal water contents measured above the 10% air-filled porosity Limit (Podolinski site). Overd, of the 12 sites, 8 did no t show any significan t nitrogen fertilizer effect across al! landscape positions. Another, the Denys site, did show a sigiuhcant fertüizer effect but the gains in yield were srnail. Remaining are only 3 sites, the McCracken, Cameron and Podolinski sites, in which significant yield gains from feridizer were observed. On these sites evidence was also seen of differential yield responses across ranges of landscape positions and soi1 characteristics. The sites with the most significant evidence of differential yield response were the McCracken and Cameron sites, perhaps because of their relatively large changes in soil properties across their landscapes. From previous work it was found that the McCracken site varied from 046% clay, 30-92% sclnci and 0.2-5-976 OC- The Cniueron site varied From 0-23% clay, 31-94% sand and 0.3- 3.1 X OC. These large variations in soil properties across landscape positions created large variations in both soi1 water and yields and resulted in clear patterns of behaviour. Quantitative analysis of the data from these two sites iridicated that yield response to fertilizer was linked to two boundary values, a Limit of extractable water (0.10-0.15 cn+/cin3 a bove the lower limit) below which yield response to fertilizer was high, and the other, a boundary of approximately 1.5-2% OC, above which soik show smd yield responses to fertilizer. Analyses thusfar show that yieId response to fertilizer can Vary across sd properties and tha t significan t yield response can be associated with the lirnits of extractable water and OC, By defining these Limits, it is now possible to define areas of management inefficiencies-For instance, application of a aN fertilizer rate on the McCracken site, in areas with OC greater than 2% would gain liffle in terms of increased y ields (in Figure 5.5). Definition of management practices based on these yield responses to soi1 properties however, should be restricted to the iimit defined by OC. Prediction of extractable water would be difficult considering the variable nature of precipitation and climate and therefore definition of management practices based upon extractable water would be unlikely. More Likely would be the definition of management areas based on the knowledge of the relationships between yield, soii water and soi1 properties. From Our previous work, it has been seen that OC was highly Linked to areas of "Ieast LinUting" water conditions, where OC was found to be linked with greater plant extractable water under drought conditions, as well as king iinked to lower water and betîer aeration conditions under saturated conditions. Based on this data and the data showing yield response to fertilizer across a range of OC, OC could be a usefd tool in Liefuiing management units for the growth of corn. 5.4 CONCLUSIONS In general, yield response to fertilizer was not seen in many of our sites- However, in those sites in which yield response to fertilizer was fourid, evidence of differential yield responses across ranges of soil properties was seen. Evident from the correlations between yields (+N and ON) and the soil properties PEW-, and OC, was that 3 sites (McCracken, Cameron and Podohski) showed a differential yield response across a range of PEW,,,,, Also evident from the yield vs. PEW,, analysis was that yidds in the ON trea tmen t seemed to be profoundly affected when PEW,, fell below 0.10-0.15 cm3/cm3. Differential yield response was also seen across a range in OC At the McCracken site, relatively large yield responses were observed in soils with low OC contents, up to an approximate 2% OC. Soils with OC contents higher than 2% showed relatively smali and constant yield response gains to fertilizer application. From our previous work, it was seen that OC was linked to areas of higher plant extractable water in drought conditions, as weil as areas of low water and better aeration in saturated conditions, Here, OC has also been hked to yield response to N fertilizer application. Clearly, OC plays a strong role in determining optimal growth conditions for corn growth and cm play a role in influencing the efficiency of management Considering the differential yield response to fertilizer across the range of plant extractable water and OC, and considering that OC has been to Wedoptimal or "least liiniting" soil water conditions, perhaps OC could be used to define different management areas. Before OC can be used to define management units however, clearer Links between OC, plant extractable water and yields mut be made. Thus far our data only estabLished the existence of sud, relationships. Clearer relationships must be made to determine where and when changes in soil water and soil properties demark significant changes in yield response, nidi that efficiencies in management cmbe improved, 5.5 REFERENCES Colvin, T.S., D. B. Jaynes, and D. L. Karlen- 1996. Yield variability within a central Iowa Field. Trans. ASAE. 40(4): 883-889. DaSilva, A.P., Kay, B.D. 1997. Estirnating the least limiting water range of soils from properties and management. Soil Sci. Soc. Am. J.61:877-883. Kay, B.D., Tellenaar, M., Dnuy, CF., YUig, J., Chrorniak, C, Zhang, T. 1999. hcreasing nitrogen use efficiency in corn production systems: quantïfying effects of quality of soi1 structure and water regixnes. Final Report to Ontario Researdi Enhancement Program, Agriculture and Agri-Food Canada, Le tey, J.1985. Relationship be tween çoii physical properties and crop productions. Adv. So il Sci. 1:277-294. Sheldrick, EH., Wang, C. 1993. Particle Size Distribution, in: Soi1 Samplîng and Methods of Analysis, M.R. Carter, Ed. PP: 499-511.Canadian Society of Soil Science. Lewis Publishers. Table 5.2. Results of regression analysis ktween Yield(0N) and average soi1 water content during the growing season for each site. Farm: Repesïon Parameters: Prediction: Yield (ON) = 3110.0 + 22513.W(8,,) (conv. tiii) E96: Elor- 7998 Y ield (ON)= 6240.w + 3361.4*(8,,) (no tiil) EC99 Elora 1999 Yield (ON) = 7ll4.lt + 1493.3*(8,,) (conv. tiii) E99: EIora 1999 Yield (ON) = 1885.7 + 19653.W(%=) (no till) McCncken (no till) Yield (ON) = 2959.2$ + 25277.0tœ(8,d Rz = 0.705 SSE = 230 x 107 Y ield (ON) = 12027.1t 1+ exp(-28.98Y(B,, - 0-136t)) R2 = n/a SSE = 7.M x 106 Podolinski (conv. tiil) Yield (ON) = 10648.0 - 9550.fF(€l,,) CN: CampNorth Yield (ON) = 558.1 + 29896$*(0,J (1iu till) CS: Giiagm Nurth Y idJ (UN)= 5-157.C3-+ M1.3'(C3,,,) (suiiv. lil l) CC: Ca~iagraSouth Yi&l(ON) = 7295.8 - 11624W(€l,) (no till) Denys (no till) Yield (ON) = 8736.q - 51212(9,,) Canieron (no till) Rz = 0.614 SSE = 223 x 107 R2 = n/a SSE = 3.52 x 10o Newconibe (no till) Yield (ON) = 1221 7.û-f - 20876.û$*(0,,) t = regression sisliflcant (p<0.05), $ = regression significant (p<0.10), all other parameter estimates are found not significant. R? values for non-linear regrestions could not be detennined. Cornparison was done using SE. Table 5.3. Results of regression analysis between yield(0N) and average plant extractable water during the gz&ing season (PEWxaJ for each site. Farm: Regression Parame tersr Prediction: ON)EC98: Elora 1998 = 2116.9 + 48508-WCPL) (conv. till) E98: Elom 1998 Yield (ON) = 5954.4t + 8737.W(PEW-) (no till) EC99.- Hom 2999 Yielci (ON) = 7619.m - 1320.8*(PEW,,) (conv. tiU) E99: Elora 1999 Yield (ON) = 1557.8 + 33825.W(PEW,,) R2 = 0.328 (no till) McCracken (no U) Yield (ON) = 47393 + 24559-w*(PEW,,) RZ = 0.363 SSE = 4% x 107 Yield (ON) = 10674.2-f Rz = n/a 1 + exp(-63.27$'(PEW,, SE= 3.a x 1P - U.lU8t)) Podolinski (conv. tiii) YielJ (UN) = 1W8.0 - 9550.tY(PEW,,) CN: Canagra North Yield (ON) = 6270.m - 30416.0 *(PEW-) (no till) CS: Canagra North Yield (ON) = 5653.4t - 13835.ff(PEWw,) (conv. till) CC: Cünagri South Yielci (ON) = 35-I.3t - 20.4820*(PEW',,) (no till) Denys (no till) Yield (ON) = 6545.lt + 9179.5*(PEW,,) Cameron (no tilI) Yield (ON) = m3.9 + 23912W(PEW,,) RZ = 0.628123 SSE = 5.05 x 107 Y ieid (ON) = 95751t R= = n/a SÇE=4.& xl(P 1 + exp(-7270*(PW,,, - 0.OC)st)) Newcoinbe (no till) Yield (ON) = l0677.O-f - 19834.O'(PM,,) .-c t = re~essionsigtùficiuiL (p Fann: Regression Parame tersr Predictioxc EC98: Elora 1998 Yield (ON) = 435l.W + '1199.1*(OC) (conv. tiü) E98: Elora 1998 Yieid (ON) = 4635,7t + 1095.4r(OC) R2 = 0.266 (no till) EC99: Elora 1999 Y ieId (ON) = 62337t + 5%.T(OC) (cotiv. till) €99: Elor- 19%) Y ield (ON) = 4379-1t+ 1(1-17.8~(OC) Rz = 0.229 (no till) McCracken (no till) Yield (ON) = 70536t + 1138.2r(OC) Rz = 0.372 SSE = 4.89 x IW Yield (ON) = 11208-5t Rz = n/a 1 + exp(-237t*(OC - 0.526t)) SSE= 1-92 x10a Pudolinski (iuiiv. till) Yield (ON) = -335.6 + 3279.4y(OC) R2 = 0.581 CN: Caiidgm Ntwtli Y idti (ON) = 3834.7 + WlU"(0C) (nu till) CS: Canagra North Yield (ON) = 26928t + 1353.9te(OC) (conv. till) CC- Canagra South Yield (ON) = 2129.3$ + 1138.w(OC) (no till) Denys (no till) YieId (ON) = 6733.3t + 4024'(0C) Y~rlci(UN) = 339S.v + 2910.1tr(OC) R= = 0.614 SE= 223 x 107 YieId (ON) = 10408.4f Rz = n/a 1 + exp(-37w(OC - O-963t)) SSE= 1.34~107 Newcornbe (no till) Y ield (ON) = 6461.4t + 965.0f (OC) t = regrc-ssion sigtiificiuii (p<0.05), $ = regression significant (p<0.10), ali other parameter estimdLes dre fouiici noi signifie-crn~. R2 values for non-hear regressions could not be determined. Conipuison wcis donc using SSE. CHAMTER 6: GENERAL CONCLUSIONS This study has demonstrated that the variabdity in yield and yidd response to fertilizer N can be infIuenced by soil structure and water content, but the lestlimiting water range (LLWR) and the critical limits associated with it, were inadequate in descnbing Limiting plant conditions. The specific conclusions were: - The W RC and SRC pedo tram fer functions derived by da Silva and Kay (1997) were inadequate in describing the water release and soil resistance mesfor our range in soils. New pedotransfer functions for both the WRC and SRC were denved. - in our sites, seasonai water contents were found to be mostly drought Iimiting for plant growth and the critical Limits under dry soil conditions defined in the LLW R, i.e. water content at a soil resistance of 2MPa (Taylor et ai., 1966; Greacen, 1986), and the water content at the permanent wiiting point (Richards and Wea ver, 1944), were inadequate in describing critically limiting conditions for corn growth. - Kay et al. (1999) defined the lower Lunit of water in which the photosynthesis of corn plants reached zero (OUp)- The seasonal average water contents rneasured above was defined as plant extractable water (PEW,) during the growing season, and was found to be signihcantly correlated with yields on many O f Our sites. Ho wever, analysis indica ted the critical need for a "threshold" limit of water content in which corn plants begiri to experience severe Iosses in health due to drying conditions. - Yield response to fertiiizer N was also found to Vary across ranges of PEW,. Organic carbon (OC) was also found to be highly correlated with yields, However, organic carbon was also linked to areas of high PEW,, dhg drought conditions, as weU as king liriked to areas of low water and good aeration during saturated conditions. In general, organic carbon was linked to those areas with the "least Limiting" water conditions. Yield response to fertilizer N was also found to vary across ranges of OC, where yield response to fertilizer N was srnall and constant at OC contents greater than 2%.Thk, combined with the data showing that OC was Iinked to areas of least limiting water conditions, indicates that OC codd be a u5efu.I tool in defining management areas that may irnprove on the efficiency in which we manage the variability in our fields. FUTURE RESEARCH A critical need in understanding the influence of soi1 structure and soil water on the variability in yields, is the clear definition of critical limits for plant growth. With clear liniits, niuch more of the variation in yields could be found. The impacts of teniporal variation of soil water, such as drought co~ditionsduring silking, could also be examined. Also, much more could be inferred into the roles of soil water and soi1 properties upon the yield response of corn to fertilizer N application. Clearly, organic carbon must also be examined more closely. What specificdy does OC con tri bu te to soil/ w a ter interactions and as consequence to yields? Also, does OC contribute to yields directly, even under non-nitrogen limiting conditions? Finaliy, the influence of soil structure and soil water at depths greater than 30cm must also be examined. lt is conceivable that soi1 properties and soil water at greater depths could explain much of the unexplained variability in yields and yield response to fertilizer seen thusfar-