DOCSLIB.ORG

Comparative Ecology of Microorganisms and Macroorganisms 2Nd Edition Download Free

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Comparative Ecology of Microorganisms and Macroorganisms 2Nd Edition Download Free COMPARATIVE ECOLOGY OF MICROORGANISMS AND MACROORGANISMS 2ND EDITION DOWNLOAD FREE John Andrews | 9781493968954 | | | | | Comparative Ecology of Microorganisms and Macroorganisms Growth and Growth Form. About this Textbook This second edition textbook offers an expanded conceptual synthesis of microbial ecology with plant and animal ecology. It is a thoughtful attempt to integrate ideas from, and develop common themes for, two fields of ecology that should not have become fragmented. The study of the rumen required Hungate to develop techniques for culturing anaerobic microbes, and he also pioneered a quantitative approach to the study of microbes and their ecological activities that differentiated the relative contributions of species and catabolic pathways. Journal of Theoretical Biology. FAQ Policy. Retrieved Biodiversity Density-dependent inhibition Ecological effects of biodiversity Ecological extinction Endemic species Flagship species Gradient analysis Indicator species Introduced species Invasive species Latitudinal gradients in species diversity Minimum viable population Neutral theory Occupancy—abundance relationship Population viability analysis Priority effect Rapoport's rule Comparative Ecology of Microorganisms and Macroorganisms 2nd edition abundance distribution Relative species abundance Species diversity Species homogeneity Species richness Species distribution Species-area curve Umbrella species. Comparative ecology of microorganisms and macroorganisms John H. Views Read Edit View history. Smith FEMS microbiology ecology Lichen is an example of a symbiotic organism. Carl Comparative Ecology of Microorganisms and Macroorganisms 2nd edition first demonstrated that the sequence of the 16S ribosomal RNA molecule could be used to analyze phylogenetic relationships. He is often incorrectly credited with framing the microbial biogeographic idea that "everything is everywhere, but, the environment selects", which was stated by Lourens Baas Becking. Has PDF. Ecological niche Ecological trap Ecosystem engineer Environmental niche modelling Guild Habitat Marine habitats Limiting similarity Niche apportionment models Niche construction Niche differentiation. Infection Control and Hospital Epidemiology. Main article: Human microbiota. These microbes play a vital role in biogeochemical cycles. Frontiers in Microbiology. Ascendency Bioaccumulation Cascade effect Climax community Competitive exclusion principle Consumer—resource interactions Copiotrophs Dominance Ecological network Ecological succession Energy quality Energy Systems Language f-ratio Feed conversion ratio Feeding frenzy Mesotrophic soil Nutrient cycle Oligotroph Paradox of the plankton Trophic cascade Trophic mutualism Trophic state index. Fungi and the evolution of growth form. The origin of mitosing cells: 50th anniversary of a classic paper by Lynn Sagan Margulis. Buy Softcover. In the home, pets can be carriers of bacteria; for Comparative Ecology of Microorganisms and Macroorganisms 2nd edition, reptiles are commonly carriers of salmonella. Among the completely updated topics in the book are phylogenetic systematics, search algorithms and optimal foraging theory, comparative metabolism, the origins of life and evolution of multicellularity, and the evolution of life cycles. Comparative Ecology of Microorganisms and Macroorganisms. Frontiers in Genetics. In such zones, chemosynthetic microbes provide energy and carbon to the other organisms. Genetic Variation. Selfish genes, the phenotype paradigm and genome evolution. Processes in microbial ecology. Journal of the History of Biology. Ecology portal Biology portal. Category Commons. Microbial ecology Figures and Tables from this paper. Carl Woese first demonstrated Comparative Ecology of Microorganisms and Macroorganisms 2nd edition the sequence of the 16S ribosomal RNA molecule could be used to analyze phylogenetic relationships. Irene C. For the journal, see Environmental Microbiology journal. Genetic Variation. Bibcode : PNAS Save to Library. We have a dedicated site for Germany. Other microbes are decomposerswith the ability to recycle nutrients from other organisms' waste products. Marine microorganism Marine viruses Marine prokaryotes Marine protists Microalgae Antarctic microorganism Coral microbiome Hydrothermal vent microbial communities Marine microbial symbiosis Microbial oxidation of sulfur Phycosphere Picoeukaryote International Census of Marine Microbes. Lichen is an example of a symbiotic organism. The explosion of molecular biology and the application of its techniques to microbiology and organismal biology have particularly demonstrated the need for interdisciplinary understanding. Share This Paper. It seems that you're in Germany. However, beginning in the s, a set of cultivation- independent techniques have evolved to determine the relative abundance of microbes in a habitat. Microbial Ecology. He was recruited to the faculty at the University of Wisconsin-Madison, where he served for 35 years teaching and doing research in the areas of microbial ecology, plant pathology, and integrated pest management, among several others. Citation Type. Ramesh; DeLaune, Ronald D. Commensalism is very common in microbial world, literally meaning "eating from the same table". Categories : Microbiology terms Bacteria Bacteriology Environmental soil science Membrane biology Biological matter Environmental microbiology Microbial population biology. About this Textbook This second edition textbook offers an expanded conceptual synthesis of microbial ecology with plant and animal ecology. Although physically small, symbiotic relationships amongst microbes are significant in eukaryotic processes and Comparative Ecology of Microorganisms and Macroorganisms 2nd edition evolution. Illustrates concepts and principles of ecological biology by referencing many forms of life Presents interdisciplinary analogies between the biology of microorganisms and macroorganisms Provides an expanded edition to include important ecological research over the past decade see more benefits. Andrews Chemoorganoheterotrophy Decomposition Detritivores Detritus. San Francisco: Benjamin Cummings. Understanding bacteria. Free Preview. Buy Softcover. The focus is the individual organism and comparisons are made along six axes: genetic variation, nutritional mode, size, growth, life cycle, and influence of the environment. Biogeochemistry of Comparative Ecology of Microorganisms and Macroorganisms 2nd edition Science and Applications. Buy Hardcover. Bibcode : Sci Srivastava, P. Oceans portal. Clinical Microbiology Reviews. Another significant breakthrough came in the s, when microelectrodes sensitive to chemical species like O2 were developed [14]. Johnstone Category Commons. Dordrecht: Kluwer Academic Publishers. Oxford: Oxford University Press. Hidden categories: Articles with short description Short description is different from Wikidata. Understanding bacteria. Nutritional Mode. The study of the rumen required Hungate to develop techniques for culturing anaerobic microbes, and he also pioneered a quantitative approach to the study of microbes and their ecological activities that differentiated the relative contributions of species and catabolic pathways. Conclusion: Commonalities and Differences in Life Histories. He was recruited to the faculty at the University of Wisconsin-Madison, Comparative Ecology of Microorganisms and Macroorganisms 2nd edition he served for 35 years teaching and doing research in the areas of microbial ecology, plant pathology, and integrated pest management, among several others. In such zones, chemosynthetic microbes provide energy and carbon to the other organisms. He received graduate degrees from the University of Maine and the University of California, Davis, followed by postdoctoral work at Cambridge University and the University of British Columbia. Namespaces Article Talk. Smith FEMS microbiology ecology From Reviews of the First Edition: "John Andrews has succeeded admirably in building a bridge that is accessible to all ecologists. Biotechnology may be used alongside microbial ecology to address a number of environmental and economic challenges. References Publications referenced by this paper. Publication Type. Bibcode : PNAS Lichen is an example of a symbiotic organism. Progress in microbial ecology has been tied to development of new technologies. The Life Cycle. From Wikipedia, the free encyclopedia. Main article: Human microbiota. Microorganisms are the backbone of all ecosystemsbut even more so in the zones where photosynthesis is unable to take place because of the absence of light. The focus is the individual organism and comparisons are made along six Comparative Ecology of Microorganisms and Macroorganisms 2nd edition genetic variation, nutritional mode, size, growth, life cycle, and influence of the environment. Comparative productivity in ecosystems—secondary productivity. Ecological niche Ecological trap Ecosystem engineer Environmental niche modelling Guild Habitat Marine habitats Limiting similarity Niche apportionment models Niche construction Niche differentiation. Figures and Tables from this paper. Among the completely updated topics in the book are phylogenetic systematics, search algorithms and optimal foraging theory, comparative metabolism, the origins of life and evolution of multicellularity, and the evolution of life cycles. For example, molecular techniques such as community fingerprinting or metagenomics can be used to track changes in microbial communities over
Load more

Recommended publications
  • REU Mentors and Projects 2018 (Updated January 11, 2018) UMBS
    REU Mentors and Projects 2018 (updated January 11, 2018) UMBS forest ecosystem study Chris Gough, Virginia Commonwealth University Luke Nave, University of Michigan Chris Vogel, University of Michigan Forests of northern Michigan provide ecosystem services including the capture and sequestration of carbon, retention of nutrients, maintenance of organismal and ecosystem diversity, and protection of surface and ground water quality. Our collaborative team conducts research on the scientific underpinnings of these ecosystem services, with particular emphasis on plant and ecosystem ecology, disturbance ecology, ecological succession, carbon and nitrogen biogeochemistry, botany and mycology. We conduct this research in a variety of settings, including a 20-year experimental forest with a long-running carbon "flux" tower, a landscape- scale experimental disturbance in which >6700 trees were stem girdled, a pair of long-term chronosequences with stands from 20 to >200 years old, and, beginning in 2018, a new experimental manipulation of disturbance severity in which tree mortality will range from 45 to 85 %. REU student collaborators on the UMBS Forest Ecosystem Study team have numerous research options. Some examples include: 1) disturbance, climate, and forest age effects on carbon cycling; 2) mechanisms sustaining high rates of carbon storage in old forests; 3) remotely sensed ecosystem structure-carbon cycling relationships; and 4) fungal processes controlling decomposition and tree nutrient supply. Effects of climate change on wetland biodiversity Amy Schrank, University of Minnesota Climate change is predicted to result in significant losses in both the amount of and the biodiversity within Great Lakes coastal wetlands. Coastal wetlands provide important ecosystem services including nursery areas for the majority of Great Lakes fish species, important habitat for wildlife including rare and endangered species, a filter for pollutants and sediment, shoreline protection against wind and waves, and many others.
    [Show full text]
  • Tree Species Associations of Pinus Echinata Mill. Over a Large-Scale Sampling Regime on the Interior Highlands of Arkansas
    TREE SPECIES ASSOCIATIONS OF PINUS ECHINATA MILL. OVER A LARGE-SCALE SAMPLING REGIME ON THE INTERIOR HIGHLANDS OF ARKANSAS James F. Rosson, Jr.1 ABSTRACT.—The Interior Highlands physiographic province of Arkansas is considered the ecological center of the geographic distribution of shortleaf pine (Pinus echinata Mill.). I used data from the U.S. Forest Service, Forest Inventory and Analysis (FIA) program to identify the major tree species associates of P. echinata across this 66,700-km2 landscape. Across the region, 41,207 km2 were covered by timberland. The study population was represented by 434 relatively undisturbed upland sample plots from the 1995 forest survey of Arkansas. P. echinata ≥12.7 cm in diameter at breast height (DBH) occurred on 211 of these sample plots. Additionally, it ranked fi rst in basal area on 119 plots, second on 39 plots, and third on 19 plots. Where P. echinata was dominant, stand basal area averaged 23.1 m2 ha-1 (± 0.57 SEM). I used chi-square to test for degree of association between the stand dominants and to test for positive and negative associations. There was a positive association between P. echinata and Quercus alba L. (χ2 = 0.490; 1df). In contrast, there was a negative association between P. echinata and Q. velutina Lam. (χ2 = 15.571; 1df). These results demonstrate that the chi- square test of association is effective even on the larger scales of sampling where lack of sample homogeneity may sometimes complicate analysis. Such quantitative tests for species associations offer meaningful insights into P. echinata communities at the landscape scale of sampling.
    [Show full text]
  • Are the Consequences If Some Algal Species Are Lost? Saarinen, Anniina; Salovius-Lauren, Sonja; Mattila, Johanna
    This is an electronic reprint of the original article. This reprint may differ from the original in pagination and typographic detail. Epifaunal community composition in five macroalgal species - What are the consequences if some algal species are lost? Saarinen, Anniina; Salovius-Lauren, Sonja; Mattila, Johanna Published in: Estuarine, Coastal and Shelf Science DOI: 10.1016/j.ecss.2017.08.009 Publicerad: 01/01/2018 Document Version (Referentgranskad version om publikationen är vetenskaplig) Document License CC BY-NC-ND Link to publication Please cite the original version: Saarinen, A., Salovius-Lauren, S., & Mattila, J. (2018). Epifaunal community composition in five macroalgal species - What are the consequences if some algal species are lost? Estuarine, Coastal and Shelf Science, 207, 402–413. https://doi.org/10.1016/j.ecss.2017.08.009 General rights Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. Take down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. This document is downloaded from the Research Information Portal of ÅAU: 11. Oct. 2021 1 1 Epifaunal community composition in five macroalgal species – what 2 are the consequences if some algal species are lost? 3 1 4 Corresponding
    [Show full text]
  • Mercury Bioaccumulation in Some Commercially Valuable Marine Organisms from Mosa Bay, Persian Gulf
    Int. J. Environ. Res., 5(3):757-762, Summer 2011 ISSN: 1735-6865 Mercury Bioaccumulation in Some Commercially Valuable Marine Organisms from Mosa Bay, Persian Gulf * Mortazavi, M. S. and Sharifian, S. Persian Gulf and Oman Sea Ecological Research Institute, P. O. Box 79145-1597 Bandar Abbas, Hormozgan, Iran Received 23 Sep. 2010; Revised 11 March 2011; Accepted 17 March 2011 ABSTRACT: This study was undertaken to determine the concentration of mercury in edible muscle of five commercially valuable marine organisms from Mosa Bay, Persian Gulf, Iran. The total mercury concentrations were determined by cold vapour atomic absorption spectrophotometry and expressed in µg/g dry weight. Certified reference materials were used for each batch of analysis. Mercury concentration was 0.373 µg/g for Liza abu, 1.172 µg/g Sparidentex hasta, 0.445µg/g for Acanthopagrus latus, 0.390 µg/g for Thunnus tonggol, and 0.360 µg/g for Fenneropenaeus indicus. Carnivorous fish had higher level of mercury than non-carnivorous. Statistical analysis revealed weak correlation between fish mercury concentration and length for all studied organisms. The observed concentrations were comparable to those found in other areas of the Persian Gulf and were lower than the WHO guideline of 0.5 mg/kg wet weight. Our result demonstrated that estimated daily and weekly intakes of mercury via consumption of fish flesh were far below the PTDI and PTWI values recommended by FAO/WHO. Key words: Mercury,Marine Organisms, Food Safety, Persian Gulf, Mosa Bay INTRODUCTION Fish is widely consumed in many parts of the world Bay disaster in Japan, which has resulted in the deaths by humans because it has high protein content, low of over 1,000 people and left over 2,000 seriously ill saturated fat and also contains omega fatty acids from contaminated seafood (Harada 1995).
    [Show full text]
  • Do Arthropod Assemblages Fit the Grassland and Savanna Biomes Of
    Research Article Arthropod assemblages of grassland and savanna in South Africa Page 1 of 10 Do arthropod assemblages fit the grassland and AUTHORS: savanna biomes of South Africa? Monique Botha1 Stefan J. Siebert1 Johnnie van den Berg1 The long-standing tradition of classifying South Africa’s biogeographical area into biomes is commonly linked to vegetation structure and climate. Because arthropod communities are often governed by both AFFILIATION: these factors, it can be expected that arthropod communities would fit the biomes. To test this hypothesis, 1Unit for Environmental Sciences we considered how well arthropod species assemblages fit South Africa’s grassy biomes. Arthropod and Management, North-West assemblages were sampled from six localities across the grassland and savanna biomes by means University, Potchefstroom, South Africa of suction sampling, to determine whether the two biomes have distinctive arthropod assemblages. Arthropod samples of these biomes clustered separately in multidimensional scaling analyses. Within CORRESPONDENCE TO: biomes, arthropod assemblages were more distinctive for savanna localities than grassland. Arthropod Monique Botha samples of the two biomes clustered together when trophic groups were considered separately, suggesting some similarity in functional assemblages. Dissimilarity was greatest between biomes for EMAIL: phytophagous and predacious trophic groups, with most pronounced differentiation between biomes [email protected] at sub-escarpment localities. Our results indicate that different arthropod assemblages do fit the grassy DATES: biomes to some extent, but the pattern is not as clear as it is for plant species. Received: 12 Nov. 2015 Significance: Revised: 26 Mar. 2016 • Provides the first comparison of arthropod composition between grassland and savanna biomes of Accepted: 06 Apr.
    [Show full text]
  • An Introduction to Evolutionary Ecology
    An Introduction to Evolutionary Ecology ANDREW COCKBURN Professor of Botany and Zoology School of Life Sciences Australian National University Canberra, Australia ILLUSTRATED BY KARINA HANSEN OXFORD BLACKWELL SCIENTIFIC PUBLICATIONS LONDON EDINBURGH BOSTON MELBOURNE PARIS BERLIN VIENNA Contents PREFACE, xi THE SCOPE OF EVOLUTIONARY ECOLOGY, 1 Patterns in the living world, 2 Why was 1983 so bad for giant pandas?, 2 Different ways of growing up, 3 Why have sex in the sea?, 6 Why does each fig have its own fig wasp?, 7 Interactions between species: a periodic table?, 11 Why are there so many species of beetles?, 12 Darwin's solution to asking why?, 13 Evolution is not a synonym of natural selection, 14 What is natural selection?, 14 Types of selection, 15 Directional, stabilising and disruptive selection, 16 Frequency-dependent selection, 16 Density-dependent and density-independent selection, 18 Hard and soft selection, 19 Natural and artificial selection, 19 Natural and sexual selection, 19 What are fitness and adaptation?, 20 The theory of natural selection is not tautologous, 20 Absolute versus relative prowess, 21 How'do we detect selection and adaptation?, 22 Summary, 23 Further reading, 23 Topics for discussion, 24 THE GENETIC BASIS OF EVOLUTIONARY CHANGE, 25 Genotype and phenotype, 26 Alleles of genes, and dominance, 28 Gene interactions, 28 Nature versus nurture and heritability, 29 How does genetic variation arise?, 32 How do allele frequencies change?, 33 The Hardy—Weinberg Law, 33 Random causes, 34 The Neutral Theory of Molecular
    [Show full text]
  • REU Mentors and Projects 2018 (Updated January 11, 2018) UMBS
    REU Mentors and Projects 2018 (updated January 11, 2018) UMBS forest ecosystem study Chris Gough, Virginia Commonwealth University Luke Nave, University of Michigan Chris Vogel, University of Michigan Forests of northern Michigan provide ecosystem services including the capture and sequestration of carbon, retention of nutrients, maintenance of organismal and ecosystem diversity, and protection of surface and ground water quality. Our collaborative team conducts research on the scientific underpinnings of these ecosystem services, with particular emphasis on plant and ecosystem ecology, disturbance ecology, ecological succession, carbon and nitrogen biogeochemistry, botany and mycology. We conduct this research in a variety of settings, including a 20-year experimental forest with a long-running carbon "flux" tower, a landscape- scale experimental disturbance in which >6700 trees were stem girdled, a pair of long-term chronosequences with stands from 20 to >200 years old, and, beginning in 2018, a new experimental manipulation of disturbance severity in which tree mortality will range from 45 to 85 %. REU student collaborators on the UMBS Forest Ecosystem Study team have numerous research options. Some examples include: 1) disturbance, climate, and forest age effects on carbon cycling; 2) mechanisms sustaining high rates of carbon storage in old forests; 3) remotely sensed ecosystem structure-carbon cycling relationships; and 4) fungal processes controlling decomposition and tree nutrient supply. Effects of climate change on wetland biodiversity Amy Schrank, University of Minnesota Climate change is predicted to result in significant losses in both the amount of and the biodiversity within Great Lakes coastal wetlands. Coastal wetlands provide important ecosystem services including nursery areas for the majority of Great Lakes fish species, important habitat for wildlife including rare and endangered species, a filter for pollutants and sediment, shoreline protection against wind and waves, and many others.
    [Show full text]
  • Read Book Habitat Pdf Free Download
    HABITAT PDF, EPUB, EBOOK Roy Simon | 96 pages | 01 Nov 2016 | Image Comics | 9781632158857 | English | Fullerton, United States Habitat PDF Book Take the quiz Citation Do you know the person or title these quotes desc For example, in Britain it has been estimated that various types of rotting wood are home to over species of invertebrate. The chief environmental factors affecting the distribution of living organisms are temperature, humidity, climate, soil and light intensity, and the presence or absence of all the requirements that the organism needs to sustain it. Bibcode : Natur. Loss of habitat is the single greatest threat to any species. In areas where it has become established, it has altered the local fire regimen to such an extant that native plants cannot survive the frequent fires, allowing it to become even more dominant. Whether from natural processes or the activities of man, landscapes and their associated habitats change over time. Biology Botanical terms Ecological terms Plant morphology terms. Dictionary Entries near habitat habitally habitancy habitant habitat habitat form habitat group habitation See More Nearby Entries. We're gonna stop you right there Literally How to use a word that literally drives some pe Retrieved 16 May Simply put, habitat destruction has reduced the majority of species everywhere on Earth to smaller ranges than they enjoyed historically. History at your fingertips. Another cause of disturbance is when an area may be overwhelmed by an invasive introduced species which is not kept under control by natural enemies in its new habitat. National Wildlife Federation. The laws may be designed to protect a particular species or group of species, or the legislation may prohibit such activities as the collecting of bird eggs, the hunting of animals or the removal of plants.
    [Show full text]
  • Observations on Non-Additive Predation: Birds and Grasshoppers
    Evolutionary Ecology Research, 2010, 12: 739–749 Observations on non-additive predation: birds and grasshoppers Gary E. Belovsky and J.B. Slade Environmental Research Center and Department of Biological Sciences, University of Notre Dame, Notre Dame, Indiana, USA ABSTRACT Background: Classic predator–prey theory assumes that predatory mortality is additive with other sources of mortality, but predatory mortality can be non-additive. If predators preferentially kill individuals already ‘doomed’ from other mortality causes, then predation can be less than additive. If predators preferentially kill individuals more likely to survive, then predation can be greater than additive. In either case, to be non-additive, predation must modify other causes of mortality such as intraspecific competition, decreasing it in the former case and increasing it in the latter. Non-additive predation also can modify selective pressures of predation and is seldom considered except when prey are much larger than their predators. Question: Can non-additive predation be observed in the most common type of predator–prey system (prey much smaller than their predators) where this is considered very unlikely? Organisms: Two sympatric grasshoppers and their avian predators. Field site: National Bison Range, Montana, USA. Methods: Field experiments to determine: (1) whether better foraging individuals survive longer in the absence of predators or if they die from non-predatory causes in the presence of predators; (2) whether predators preferentially kill better or poorer foragers; and (3) how predators affect prey populations. Conclusions: Both grasshoppers exhibit intraspecific competition with better foragers surviving longer. Both experience high predation rates, but their populations respond differently to predation.
    [Show full text]
  • Ecological Lands Handbook June 2003
    King County Water and Land Resources Division Ecological Lands Handbook June 2003 King County Water and Land Resources Division Ecological Lands Handbook June 2003 Alternate formats available 296-6519 or TTY Relay: 711 Ecological Lands Handbook_Final_June 2003.doc Acknowledgments Project Team (*=principal author): Ingrid Lundin*, Natural Resource Planner, Natural Resource Lands Management, Water and Land Resources Division (WLRD) Jennifer Vanderhoof*, Ecologist, Watershed and Ecological Assessment, WLRD Deb Snyder, Natural Resource Planner, Natural Resource Lands Management, WLRD Jennifer Thomas, Senior Ecologist, Watershed and Ecological Assessment, WLRD Advisory Group: Natural Resource Lands Management Program, WLRD Connie Blumen, Program Coordinator Tina Miller, Volunteer Coordinator Jenna Tilt, Natural Resource Planner Michael Beevers, Natural Resource Planner Park Resource Section, Parks and Recreation Division (PRD) Bobbi Wallace, Manager David Kimmett, Resource Coordinator Scott Snyder, Resource Coordinator Steve Williams, Resource Coordinator Interpretive Program Office, PRD Chuck Lennox, Interpretive Program Coordinator Chris Mayo, Interpretive Program Coordinator Program Development and Land Management Division, DNRP Sharon Claussen, Project Manager Land and Water Stewardship Services, WLRD Clint Loper, Watershed Stewardship Unit Manager Anne Bikle, Cedar River Basin Steward Kirk Anderson, Snoqualmie River Basin Steward Flood Hazard Reduction Services, WLRD Jennifer Knauer, Program Analyst John Koon, Engineer Priscilla Kaufmann,
    [Show full text]
  • 1 the Effects of Size, Distance and History on Urban Forest Patches
    The Effects of Size, Distance and History on Urban Forest Patches Mark Sahm SPEA B.S.E.S. [email protected] Keywords: urban forest, biodiversity, site history, distance, site area Abstract The urban forest is composed of varying sizes of patches of trees across the landscape with different histories. The literature in urban ecology has found a correlation between size of these patches of forest and species homogeneity (Hobbs 1988, Godefroid and Koedam 2003). The purpose of this study is to find the effects of three variables on the urban forest: distance from a continuous forest, area of the patch, and site history. The study investigates how these variables can affect the species diversity, composition, and growth. Several sites within the City of Bloomington and on Indiana University campus have been selected. The study expected to find a relationship between higher species diversity, greater number of invasive species and larger edge habitats. However, the study found no correlations between species diversity, site history, site area and distance from the rural forest. 1 Introduction Biodiversity is an important subject when exploring and observing the urban forest. This can be used to evaluate the health of the ecosystem as well as help the resilience of the same. In recent history, humans have altered the forests compositions through changing the regime of disturbances in which these trees have evolved to live, allowing some species to decline and allowing other species to thrive (Redmend et al. 2012). Species of oak (Quercus) and hickory (Carya) dominate the forests of southern Indiana and the suppression of natural processes is causing the forest to change, having more shade tolerant species of maple (Acer) and beech (Fagus) (Pierce et al.
    [Show full text]
  • Is the Macrophyte Diversification Along the Trophic Gradient Distinct Enough for River Monitoring?
    Environ Monit Assess (2017) 189:4 DOI 10.1007/s10661-016-5710-8 Is the macrophyte diversification along the trophic gradient distinct enough for river monitoring? Krzysztof Szoszkiewicz & Anna Budka & Karol Pietruczuk & Dariusz Kayzer & Daniel Gebler Received: 9 May 2016 /Accepted: 18 November 2016 # The Author(s) 2016. This article is published with open access at Springerlink.com Abstract The variation of a number of parameters char- gradient. We confirmed that vegetation diversification acterizing aquatic plant assemblages in rivers across a along a trophic gradient is evident enough to detect wide trophic gradient was investigated to evaluate their degradation in a five quality class system. usefulness for a Polish national river monitoring system. Analyses were conducted at 100 sites included in the Keywords Rivers . Macrophytes . Trophy . Freshwater national river monitoring system, representing a uni- assessment . Ecological status form river type, i.e., small- and medium-sized lowland rivers with a sandy substrate. Results of botanical sur- veys, which were supplemented with comprehensive Introduction monthly quality records, were obtained from the nation- al monitoring database. By analyzing the Jaccard dis- Macrophytes are aquatic plants growing in water which tances of the botanical metrics using the adonis function, are large enough to be visible with the naked eye and are the variation in species composition between rivers of almost always identifiable in the field. They include different trophic status was determined. The group higher aquatic plants, vascular cryptograms, and bryo- consisting of the most degraded rivers was the most phytes, as well as structural macroalgae (Westlake 1975; homogeneous in terms of botanical composition.
    [Show full text]