DOCSLIB.ORG

Open Trampush Dissertation Final Draft 2017 11 21.Pdf

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Open Trampush Dissertation Final Draft 2017 11 21.Pdf The Pennsylvania State University The Graduate School Department of Geosciences HOW LANDSCAPE DYNAMICS CAN ALTER THE PRESERVATION AND INTERPRETATION OF PALEOENVIRONMENTAL SIGNALS IN FLUVIODELTAIC ENVIRONMENTS A Dissertation in Geosciences by Sheila M. Trampush © 2017 Sheila M. Trampush Submitted in Partial Fulfillment of the Requirements for the Degree of Doctor of Philosophy December 2017 The dissertation of Sheila M. Trampush was reviewed and approved* by the following: Elizabeth Hajek Assistant Professor of Geosciences Dissertation Adviser Chair of Committee Lee Kump Professor of Geosciences Mark Patzkowsky Professor of Geosciences Benjamin Shaby Assistant Professor of Statistics Demien Saffer Professor of Geosciences Head of Graduate Programs and Research in the Department of Geosciences *Signatures are on file in the Graduate School iii ABSTRACT Fluviodeltaic environments are some of the most dynamic sedimentary systems on Earth. They are highly sensitive to changes in external boundary conditions, such as sea level, sediment supply, and climate. In addition, they have a wide range of internally generated (autogenic) sediment transport processes that control where sediment is deposited or eroded over short to intermediate timescales (up to ~105 years). Example of these autogenic processes include channel avulsion or bifurcation. Because of the highly dynamic nature of fluviodeltaic environments, it is hard to predict how they will respond to future changes in sea level and climate. However, they are critical environments for society, and so efforts have focused on better understanding how they have responded to perturbations in the stratigraphic record in order to better predict the future. The challenge of directly applying analyses of the stratigraphic record is that the very landscape dynamics that make it hard to predict delta behavior in the future, complicate the preservation and interpretation of past paleoenvironmental signals of all sorts. The autogenic processes in particular cause sediment to be unevenly deposited in both time and space. This means that the stratigraphic record of paleoenvironmental signals is likely to have large amounts of missing time at any given study location within a fluviodeltaic system. Previous work has demonstrated that autogenic processes, and the gaps in the record caused by autogenic processes, can expand, condense, or remove entire portions of paleoenvironmental signals if they occur at timescales less than the longest timescale autogenic processes. In this dissertation, I use a combination of numerical models and field datasets to explore how landscape dynamics control signal preservation and how we can use landscape dynamics to improve the uncertainties related to reconstructing paleoenvironmental signals in dynamic landscapes. iv In the first project of this dissertation, I investigate how to measure the scale of landscape dynamics using depositional patterns preserved in outcrops that are limited in spatial extent or resolution. To accomplish this I used synthetic stratigraphy from a physical delta experiment to test the sensitivity of a proposed tool to identify the maximum autogenic scale, called the compensation statistic. I also applied this analysis to four field fluviodeltaic datasets. In the second project, I demonstrate the effect of stochastic sedimentation from landscape dynamics on the probability of preservation and the accuracy of reconstructions of paleoenvironmental signals from geochemical paleoenvironmental proxies. To this end, I compiled sedimentation event magnitudes and frequencies from published data from modern and ancient river, delta, and shallow shelf environments. Based on this compilation, I wrote a stochastic sedimentation model that tracked the preservation of an input proxy signal. In the third project, I investigate how autogenic landscape dynamics control the spatiotemporal distribution of erosion and deposition across a fluviodeltaic system using a numerical delta evolution model. I then used multiple models to predict how these landscape dynamics control how many samples are needed to reconstruct complete and accurate reconstructions of paleoenvironmental signals of different durations. Finally, I applied the concepts developed in the first three projects to a case of the preservation of the Paleocene-Eocene Thermal Maximum, a rapid global warming event ~56 Ma, within deltaic and shelf deposits from the Mid-Atlantic. Overall, this dissertation demonstrates that rapid paleoenvironmental signals can be reconstructed even in highly dynamic sedimentary system when the system is sampled sufficiently to overcome the combined effects of landscape dynamics. Additionally, my analyses demonstrate that under-sampled fluviodeltaic systems are highly likely to significantly bias reconstructions of the original signal. v TABLE OF CONTENTS List of Figures .......................................................................................................................... viii List of Tables ........................................................................................................................... x Acknowledgements .................................................................................................................. xi Chapter 1 Introduction to landscape dynamics and the stratigraphic record ........................... 1 1.1 Distinguishing Climate Change from Landscape Dynamics ..................................... 3 1.2 Dissertation Goals and Approach ............................................................................... 6 1.3 Summary of Dissertation Chapters ............................................................................ 7 Chapter 2: Identifying autogenic sedimentation in fluvial-deltaic stratigraphy: evaluating the effect of outcrop-quality data on the compensation statistic ..... 7 Chapter 3: Preserving proxy records in dynamic landscapes: Modeling and examples from the Paleocene-Eocene Thermal Maximum .............................. 8 Chapter 4: Exploring how landscape dynamics influence the sampling of paleoenvironmental signals .............................................................................. 8 Chapter 5: Characterizing landscape dynamics and variability in sedimentation on the Mid-Atlantic shelf during the Paleocene-Eocene Thermal Maximum .. 9 1.4 References .................................................................................................................. 10 Chapter 2 Identifying autogenic sedimentation in fluvial-deltaic stratigraphy: evaluating the effect of outcrop-quality data on the compensation statistic ...................................... 13 Key Points ........................................................................................................................ 13 Abstract ............................................................................................................................ 13 2.1 Introduction ................................................................................................................ 14 2.2 Background ................................................................................................................ 17 2.2.1 Identifying autogenic scales and organization using the compensation statistic .............................................................................................................. 20 2.3 Effects of dataset resolution on autogenic scales and organization estimates ........... 24 2.3.1 Dataset extent .................................................................................................. 25 2.3.2 Dataset resolution ............................................................................................ 27 2.3.3 Implications ..................................................................................................... 28 2.4 Identifying autogenic scales and organization in ancient fluvial and deltaic deposits ..................................................................................................................... 30 2.4.1 Fluvial case studies .......................................................................................... 31 2.4.2 Deltaic case studies ......................................................................................... 37 2.5 Discussion .................................................................................................................. 44 2.6 Conclusions ................................................................................................................ 48 Acknowledgments and Data ............................................................................................ 49 References ........................................................................................................................ 50 2.7 Figures and Tables ..................................................................................................... 56 vi Chapter 3 Preserving proxy records in dynamic landscapes: Modeling and examples from the Paleocene-Eocene Thermal Maximum ...................................................................... 69 Abstract ............................................................................................................................ 69 3.1 Introduction ................................................................................................................ 70 3.2 Stochastic Sedimentation Model ...............................................................................
Load more

Recommended publications
  • Final Report Analysis of Sediment Cores from the West Bay Diversion Receiving Area
    Final Report Analysis of Sediment Cores from the West Bay Diversion Receiving Area Alexander S. Kolker Louisiana Universities Marine Consortium 1. Introduction A. The setting. The Mississippi River Delta has one of the highest rate of land loss of any system on Earth. Present day rates of land loss average about 62 km2 yr‐1, and exceeded 100 km2 yr‐1 during the 1970s (Barras et al., 2003; Day et al., 2007). The causes of this land loss are numerous and a partial list includes high rates of subsidence, reduced sediment deposition, changes in the tidal prism of the delta's coastal bays, global sea level rise, hurricane impacts, salt water intrusion, canal construction, invasive species, and biogeochemical changes that are unfavorable for plant growth (Barras, 2006; Darby and Turner, 2008; Day et al., 2007; Fitzgerald et al., 2004; Gagliano et al., 1981; Kolker et al., 2010; Reed, 2002; Tornqvist et al., 2008). These drivers of wetland loss exist on a landscape that naturally experiences cycles of land gain and loss that result from changes in the course of the Mississippi River and occur on time scales decades to millennia (Coleman, 1988; Roberts, 1997; Tornqvist et al., 1996; Wells and Coleman, 1987). One potentially powerful way to restore the Mississippi River Delta is to partially divert the flow of the Mississippi River, thereby allow sediments and freshwater to enter the coastal landscape in a manner that mimics natural land‐building processes (Day et al., 2007; LACPRA, 2007; LADNR, 1998). Several natural and semi‐natural diversions provide strong evidence of the potential for river diversions to build land.
    [Show full text]
  • Uplift Rate Transients at Subduction Margins Due to Earthquake Clustering
    Originally published as: Mouslopoulou, V., Oncken, O., Hainzl, S., Nicol, A. (2016): Uplift rate transients at subduction margins due to earthquake clustering. - Tectonics, 35, 10, pp. 2370—2384. DOI: http://doi.org/10.1002/2016TC004248 PUBLICATIONS Tectonics RESEARCH ARTICLE Uplift rate transients at subduction margins due 10.1002/2016TC004248 to earthquake clustering Key Points: Vasiliki Mouslopoulou1, Onno Oncken1, Sebastian Hainzl1, and Andrew Nicol2 • Transient uplift rates along fore-arc settings due to earthquake clustering 1German Research Centre for Geosciences, GFZ Helmholtz Centre Potsdam, Potsdam, Germany, 2Department of Geological • Earthquakes nucleate mostly on upper plate splay faults and less on the plate Sciences, University of Canterbury, Christchurch, New Zealand interface • Late Quaternary paleoshorelines may provide seismic hazard information Abstract Coastal uplift is common in continental fore-arc systems, with elevated paleoshorelines along seismically quiet subduction indicating that uplift rates can vary dramatically over time on individual margins. The origins of these margins changes in uplift rates are examined using a global data set of paleoshorelines together with 2-D numerical models of subduction systems. Empirical paleoshoreline data (N = 282) from eight subduction margins Supporting Information: indicate that uplift rates are generally not steady state and varied by up to a factor of 20 during the late • Supporting Information S1 ≤ fi • Table S1 Quaternary ( 125 ka). On many subduction margins uplift rates increase to the present day, a nding which • Supporting Information S2 we attribute to sampling bias toward those locations where Holocene uplift rates have been highest (with respect to other global margins which have undergone fast subsidence or no vertical motion—e.g., a Correspondence to: property akin to the so-called Sadler effect).
    [Show full text]
  • The Stratigraphy Machine Andrew D
    The Stratigraphy Machine Andrew D. Miall, University of Toronto John H. Holbrook, Texas Christian University Summary The stratigraphic record is constructed by multiple geological processes acting over time scales as short as a few seconds to as long as hundreds of millions of years. The probability of preservation of the products of high-frequency processes is very low. The full range of depositional and removal processes constitutes what may be termed a “Stratigraphy Machine.” Sedimentation rates and time scales Peter Sadler (1981) generated a graph that has long puzzled geologists – he Figure 1. Sadler’s (1981) relationship explained demonstrated that sedimentation rates in terms of the range of geological processes vary inversely with the duration of the that generate the sedimentary record. The elapsed time over which these rates are numbers in the boxes refer to a proposed measured, from the temporary flood-plain “Sedimentation Rate Scale” (Miall, 2015). deposits beside a river to the complete fill of a major sedimentary basin. This relationship has been referred to as the “Sadler effect.” Lengthy sections representing long time periods include a large number of sedimentary breaks. In fact, Ager (1973) remarked that the sedimentary record is “more gap than record.” However, it has taken the maturation of sedimentology and stratigraphy to provide a complete explanation of the Sadler effect. The science of stratigraphy has been revolutionized over the last fifty years. The emergence of sequence stratigraphy as the standard method for documentation and analysis, the increased sophistication of facies analysis and other sedimentological methods of documentation and interpretation, and the increasing accuracy and precision of the Geological Time Scale, have enabled ever more refined interpretations of geological processes.
    [Show full text]
  • Shelf Sedimentation on a Tectonically Active Margin: a Modern Sediment Budget for Poverty Continental Shelf, New Zealand
    ARTICLE IN PRESS MARGO-04425; No of Pages 13 Marine Geology xxx (2009) xxx–xxx Contents lists available at ScienceDirect Marine Geology journal homepage: www.elsevier.com/locate/margeo Shelf sedimentation on a tectonically active margin: A modern sediment budget for Poverty continental shelf, New Zealand Andrea J. Miller, Steven A. Kuehl ⁎ Virginia Institute of Marine Science, 1208 Greate Road, P.O. Box 1346, Gloucester Point, VA 23062, USA article info abstract Available online xxxx The combination of high sediment yields and the prevalence of tectonically controlled accommodation on collision margins such as that adjacent to the Waipaoa River, NZ, create the potential for these areas to Keywords: contain high-resolution records of natural and anthropogenic signals. This study describes modern (100-yr) Waipaoa River sedimentation patterns off the Waipaoa and quantifies a sediment budget for the continental shelf, which is continental margin compared to long-term Holocene trends. 210Pb and 239,240Pu geochronologies reveal three main shelf shelf sedimentation depocenters. Two of these depocenters are located in subsiding synclinal basins on the mid-shelf, landward 210Pb geochronology 239,240Pu geochronology of the actively deforming Ariel and Lachlan anticlines. The depocenters exhibit accumulation rates ranging −1 210 fi sediment budget from 0.75 to 1.5cmyr and display both steady-state and non-steady-state Pb activity pro les. Textural characteristics of the non-steady-state cores indicate the possible preservation of flood event layers. The third depocenter is located near the shelf break and has accumulation rates as high as 1.0cmyr−1. The inner shelf and central mid-shelf are characterized by low, uniform 210Pb activity profiles and low accumulation rates, indicating that sediment is bypassing the inner shelf region and being deposited on the mid- to outer shelf.
    [Show full text]
  • Modeling Burial and Thermal History of the Central European Basins and Comparison with Organic Maturity Data
    Modeling burial and thermal history of the central European basins and comparison with organic maturity data Master’s thesis submitted in fulfilment of the requirements for the degree Master of Science (M.Sc.) in Geoscience January 2017 Georg-August-University Göttingen Faculty of Geosciences and Geography Department of Structural Geology and Geodynamics Geoscience Center by Tom Kaltofen Born in Berlin Supervisor: Dr. Elco Luijendijk Co-supervisor: Prof. Dr. Jonas Kley Contents Contents Abstract ......................................................................................................................................... III 1 Introduction .................................................................................................................................. 4 1.1 Paleozoic geological history of the study area .......................................................................... 5 1.2 Mesozoic geological history ..................................................................................................... 8 2 Methods........................................................................................................................................ 9 2.1 Burial and thermal history model ............................................................................................. 9 2.2 Input of thermal history model ................................................................................................. 9 2.3 Lithology ................................................................................................................................
    [Show full text]
  • Lack of a Weathering Signal with Increased Cenozoic Erosion?
    Received: 10 September 2016 | Revised: 27 May 2017 | Accepted: 2 June 2017 DOI: 10.1111/ter.12278 DEBATE ARTICLE Forum: The Editors of Terra Nova invite readers to contribute to a discussion of this topic on our forum at https://terranovadebates. wordpress.com/ Lack of a weathering signal with increased Cenozoic erosion? Kevin P. Norton1 | Fritz Schlunegger2 1School of Geography, Environment and Earth Sciences, Victoria University of Abstract Wellington, Wellington, New Zealand The Late Cenozoic has been marked by large and rapid fluctuations in temperature. 2Institute of Geological Sciences, University This cooling has been attributed to accelerated erosion, with concomitant increased of Bern, Bern, Switzerland chemical-weathering rates and CO2 drawdown from the atmosphere. At the same Correspondence time, much of the supporting evidence appears to be affected by a sampling bias, Dr. Kevin Norton, School of Geography, Environment and Earth Sciences, Victoria implying that global erosion and weathering have remained largely constant over University of Wellington, Wellington, the past millions of years. We suggest that sedimentary archives of geomorphic New Zealand. Email: [email protected] activity, such as grain size and the ratio of terrestrial to oceanic sedimentation, which show accelerated erosion are not subject to these biases. Furthermore, the active tectonic settings where these erosion increases were likely to have taken place are exactly those locations where chemical-weathering signals are least likely to faithfully follow physical erosion rates. A lack of evidence for an increase in chemical weathering does not necessarily preclude an increase in physical erosion. In this contribution, we suggest an alternative interpretation in which erosion rates have increased in the Late Cenozoic but without significantly increased silicate weathering, which can explain the meagre response of chemical-weathering proxies.
    [Show full text]
  • 2021 Northeast Geobiology Symposium April 9Th and 10Th Dartmouth College, Hanover, NH Talks Session 1: Proterozoic Earth 9:05 A.M
    2021 Northeast Geobiology Symposium April 9th and 10th Dartmouth College, Hanover, NH Talks Session 1: Proterozoic Earth 9:05 a.m. The rise of phosphorus recycling facilitated Earth's Great Oxidation Event Lewis J. Alcott, Benjamin J. W. Mills, Andrey Bekker, and Simon W. Poulton The rise of atmospheric oxygen during the Great Oxidation Event (GOE) ∼2.4 billion years ago (Ga) was a defining transition in the evolution of global biogeochemical cycles and life on Earth. There is, however, abundant evidence for mild oxidative continental weathering and the development of ocean oxygen oases several hundred million years prior to the GOE. The GOE thus represents a threshold, whereby primary productivity and O2 production overwhelmed the input of reduced species that consume O2, and its timing is assumed to be related to a balance between the riverine input of the major limiting nutrient, phosphate, and the dynamics of the solid Earth. However, the sequence of events that ultimately facilitated persistent atmospheric oxygenation remains elusive. Here, we report novel geochemical analyses of ∼2.65 to 2.43 Ga drill core samples from the Transvaal Supergroup, South Africa, which document an early rise of sedimentary phosphorus recycling as dissolved sulfide became more abundant in the ocean system, which itself was a progressive response to the onset of oxidative continental weathering. Biogeochemical modelling of the global implications for primary productivity shows that the evolution of phosphorus recycling was the critical step that enabled Earth's transition to a persistently oxygenated atmosphere. 9:25 a.m. Depositional rates in the Ediacaran Nafun Group, Oman, and the wider late Proterozoic world Marjorie D.
    [Show full text]
  • How Is Sea Level Change Encoded in Carbonate Stratigraphy? ∗ Emily C
    Earth and Planetary Science Letters 560 (2021) 116790 Contents lists available at ScienceDirect Earth and Planetary Science Letters www.elsevier.com/locate/epsl How is sea level change encoded in carbonate stratigraphy? ∗ Emily C. Geyman a, , Adam C. Maloof a, Blake Dyer a,b a Department of Geosciences, Princeton University, Princeton, NJ, United States of America b Department of Earth and Ocean Sciences, University of Victoria, Victoria, BC, Canada a r t i c l e i n f o a b s t r a c t Article history: The history of organismal evolution, seawater chemistry, and paleoclimate is recorded in layers of Received 14 September 2020 carbonate sedimentary rock. Meter-scale cyclic stacking patterns in these carbonates often are interpreted Received in revised form 29 December 2020 as representing sea level change. A reliable sedimentary proxy for eustasy would be profoundly useful Accepted 26 January 2021 for reconstructing paleoclimate, since sea level responds to changes in temperature and ice volume. Available online xxxx However, the translation from water depth to carbonate layering has proven difficult, with recent surveys Editor: J.P. Avouac of modern shallow water platforms revealing little correlation between carbonate facies (i.e., grain size, Keywords: sedimentary bed forms, ecology) and water depth. We train a convolutional neural network with satellite 2 carbonates imagery and new field observations from a 3,000 km region northwest of Andros Island (Bahamas) cycles to generate a facies map with 5 m resolution. Leveraging a newly-published bathymetry for the same stratigraphy region, we test the hypothesis that one can extract a signal of water depth change, not simply from sedimentary facies individual facies, but from sequences of facies transitions analogous to vertically stacked carbonate strata.
    [Show full text]
  • Debate Article Lack of a Weathering Signal with Increased Cenozoic
    Debate Article doi: 10.1111/ter.12278 1 Lack of a weathering signal with increased Cenozoic erosion? 2 3 Kevin P Norton1 and Fritz Schlunegger2 4 1 School of Geography, Environment and Earth Sciences, Victoria University of Wellington, 5 Wellington, New Zealand 6 2 Institute of Geological Sciences, University of Bern, Bern, Switzerland 7 8 Abstract 9 The Late Cenozoic has been marked by large and rapid fluctuations in temperature. This cooling has 10 been attributed to accelerated erosion with concomitant increased chemical weathering rates and 11 CO2 drawdown from the atmosphere. At the same time, much of the supporting evidence appears to 12 be affected by a sampling bias implying that global erosion and weathering remained largely 13 constant over the past millions of years. We suggest that sedimentary archives of geomorphic 14 activity such as grain size and the ratio of terrestrial to oceanic sedimentation which show 15 accelerated erosion are not subject to these biases. Furthermore, the active tectonic settings where 16 these erosion increases were likely to have taken place are exactly those locations where chemical 17 weathering signals are least likely to faithfully follow physical erosion rates. A lack of evidence for an 18 increase in chemical weathering does not necessarily preclude an increase in physical erosion. In this 19 contribution, we suggest an alternative interpretation in which erosion rates have increased in the 20 Late Cenozoic but without significantly increased silicate weathering which can explain the meagre 21 response of chemical weathering proxies. 22 23 Introduction 24 Many recent papers have highlighted a lack of consensus on our understanding of how, and even if, 25 climate impacts landscape change over geologic timescales (e.g.
    [Show full text]
  • On the Geological Significance of Clastic Parasequences ⁎ Luca Colombera , Nigel P
    Earth-Science Reviews xxx (xxxx) xxxx Contents lists available at ScienceDirect Earth-Science Reviews journal homepage: www.elsevier.com/locate/earscirev On the geological significance of clastic parasequences ⁎ Luca Colombera , Nigel P. Mountney School of Earth & Environment, University of Leeds, LS2 9JT Leeds, UK ARTICLE INFO ABSTRACT Keywords: Parasequences recognized in clastic sedimentary successions of shallow-marine origin are considered by some Sequence stratigraphy geologists to be the fundamental building blocks of depositional sequences, even though problems in their de- Shallow marine finition and application have been identified by others, who instead advocate their abandonment asformal Shoreface sequence stratigraphic units. Delta lobe To elucidate the geological significance of clastic parasequences and inform the debate on their usein Sea level stratigraphy, a quantitative characterization of the geometry, facies characteristics and timescale of deposition of Autogenic 1163 parasequences has been undertaken based on a synthesis of data from outcrop and subsurface studies that are available in the scientific literature. Through a database compilation, the attributes of the studied para- sequences are analysed with respect to the interpreted geological origin of the units, and with consideration of sources of bias and uncertainty. Particular emphasis is placed on assessing the following: (i) the importance of heuristics, and of data types and coverage in the recognition of parasequences; (ii) differences in parasequence characteristics observed across deltaic and shoreface depositional systems, and between the Quaternary and the ancient rock record; (iii) possible explanations for the range in timescales of deposition of parasequences; and (iv) the role of autogenic dynamics on the development of deltaic parasequences, partly based on a comparison with the recent evolution of modern deltas.
    [Show full text]
  • Human and Climate Global-Scale Imprint on Sediment Transfer During
    Supplementary Information for Human and climate influences on sediment transfers – a global account for the Holocene Authors: Jean-Philippe Jenny, Sujan Koirala, Irene Gregory-Eaves, Pierre Francus, Christoph Niemann, Bernhard Ahrens, Victor Brovkin, Alexandre Baud, Antti E. K. Ojala, Alexandre Normandeau, Bernd Zolitschka, Nuno Carvalhais Corresponding Author: [email protected] This PDF file includes: Supplementary text Figures S1 to S9 Dataset S1 to S5 SI References 1 www.pnas.org/cgi/doi/10.1073/pnas.1908179116 Supplementary Information Text SAR as proxy of erosion Sediment accumulation is the process of settling or being deposited to the basin floor, leading to the preservation of strata. Sediment particles originate from erosion and transport, or bio-precipitation (1). Long-term monitoring of sediment loads in rivers of the world provides a key source of evidence for assessing recent changes in soil erosion, but such records rarely extend back more than fifty years. Still, many opportunities exist to exploit the natural archives preserved within lake sediments, riverbanks, deltas, alluvial and colluvial soils to extend contemporary records, and provide evidence of changes in soil erosion over a range of time scales from decades to millennia. Among these archives, lake sediments can provide a consistent record of impact on erosion, given their normally continuous accumulation and their catchment-wide origins (2). An estimation of the quantity of material deposited in the lake may be difficult to interpret in terms of specific catchment-erosion relationships (3). Sediment reaching the lake bed will reflect not only the transport energy in the catchment but also the availability of sediment for erosion and the time lags in the system as material moves towards the lake bed via temporary sediment storage zones such as floodplains and deltas.
    [Show full text]
  • Real and Apparent Changes in Sediment Deposition Rates Through Time Rina Schumer1 and Douglas J
    JOURNAL OF GEOPHYSICAL RESEARCH, VOL. 114, F00A06, doi:10.1029/2009JF001266, 2009 Real and apparent changes in sediment deposition rates through time Rina Schumer1 and Douglas J. Jerolmack2 Received 15 January 2009; revised 11 May 2009; accepted 2 July 2009; published 30 September 2009. [1] Field measurements show that estimated sediment deposition rate decreases as a power law function of the measurement interval. This apparent decrease in sediment deposition has been attributed to completeness of the sedimentary record; the effect arises because of incorporation of longer hiatuses in deposition as averaging time is increased. We demonstrate that a heavy-tailed distribution of periods of nondeposition (hiatuses) produces this phenomenon and that observed accumulation rate decreases as tgÀ1, over multiple orders of magnitude, where 0 < g 1 is the parameter describing the tail of the distribution of quiescent period length. By using continuous time random walks and limit theory, we can estimate the actual average deposition rate from observations of the surface location over time. If geologic and geometric constraints place an upper limit on the length of hiatuses, then average accumulation rates approach a constant value at very long times. Our model suggests an alternative explanation for the apparent increase in global sediment accumulation rates over the last 5 million years. Citation: Schumer, R., and D. J. Jerolmack (2009), Real and apparent changes in sediment deposition rates through time, J. Geophys. Res., 114, F00A06, doi:10.1029/2009JF001266. 1. Introduction pattern as the ‘‘Sadler effect.’’ Sadler [1981] recognized that this decrease likely results from the intermittent nature of [2] Estimating erosion and deposition rates through geo- sediment deposition.
    [Show full text]