[PDF] Biophysical Ecology eBook

Author : David M. Gates
Publisher : Courier Corporation
Page : 642 pages
File Size : 43,26 MB
Release : 2012-04-26
Category : Science
ISBN : 0486140792

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This classic and highly influential text presents a uniquely comprehensive view of the field of biophysical ecology. In its analytical interpretation of the ecological responses of plants and animals to their environments, it draws upon studies of energy exchange, gas exchange, and chemical kinetics. The first four chapters offer a preliminary treatment of the applications of biophysical ecology, discussing energy and energy budgets and their applications to plants and animals, and defining radiation laws and units. Succeeding chapters concern the physical environment, covering the topics of radiation, convection, conduction, and evaporation. The spectral properties of radiation and matter are reviewed, along with the geometrical, instantaneous, daily, and annual amounts of both shortwave and longwave radiation. The book concludes with more elaborate analytical methods for the study of photosynthesis in plants and energy budgets in animals, in addition to animal and plant temperature responses. This text will prove of value to students and environmental researchers from a variety of fields, particularly ecology, agronomy, forestry, botany, and zoology.

Author : D.M. Gates
Publisher : Springer Science & Business Media
Page : 602 pages
File Size : 12,53 MB
Release : 2012-12-06
Category : Science
ISBN : 3642878105

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A symposium on biophysical ecology was held at The University of Michigan Biological Station on Douglas Lake August 20-24, 1973. Biophysical ecology is an approach to ecology which uses fundamental principles of physics and chemistry along with mathematics as a tool to understand the interactions between organisms and their environment. It is fundamentally a mechanistic approach to ecology, and as such, it is amenable to theoretical modeling. A theoretical model applied to an organism and its interactions with its environ ment should include all the significant environmental factors, organism properties, and the mechanisms that connect these things together in an appropriate organism response. The purpose of a theoretical model is to use it to explain observed facts and to make predictions beyond the realm of observation which can be verified or denied by further observation. If the predictions are confirmed, the model must be reasonably complete except for second or third-order refinements. If the pre dictions are denied by further observation, one must go back to the basic ideas that entered the model and decide what has been overlooked or even what has been included that perhaps should not have been. Theoretical modeling must always have recourse to experiment in the laboratory and observation in the field. For plants, a theoretical model might be formulated to explain the manner and magnitude by which various environmental factors affect leaf temperature.

Author : D.M. Gates
Publisher : Springer
Page : 0 pages
File Size : 43,83 MB
Release : 2012-04-20
Category : Science
ISBN : 9783642878121

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A symposium on biophysical ecology was held at The University of Michigan Biological Station on Douglas Lake August 20-24, 1973. Biophysical ecology is an approach to ecology which uses fundamental principles of physics and chemistry along with mathematics as a tool to understand the interactions between organisms and their environment. It is fundamentally a mechanistic approach to ecology, and as such, it is amenable to theoretical modeling. A theoretical model applied to an organism and its interactions with its environ ment should include all the significant environmental factors, organism properties, and the mechanisms that connect these things together in an appropriate organism response. The purpose of a theoretical model is to use it to explain observed facts and to make predictions beyond the realm of observation which can be verified or denied by further observation. If the predictions are confirmed, the model must be reasonably complete except for second or third-order refinements. If the pre dictions are denied by further observation, one must go back to the basic ideas that entered the model and decide what has been overlooked or even what has been included that perhaps should not have been. Theoretical modeling must always have recourse to experiment in the laboratory and observation in the field. For plants, a theoretical model might be formulated to explain the manner and magnitude by which various environmental factors affect leaf temperature.

Author : Gaylon S. Campbell
Publisher : Springer Science & Business Media
Page : 296 pages
File Size : 35,80 MB
Release : 2012-12-06
Category : Science
ISBN : 1461216265

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From reviews of the first edition: "well organized . . . Recommended as an introductory text for undergraduates" -- AAAS Science Books and Films "well written and illustrated" -- Bulletin of the American Meteorological Society

Author : Park S. Nobel
Publisher : W H Freeman & Company
Page : 608 pages
File Size : 48,80 MB
Release : 1983
Category : Cell physiology
ISBN : 9780716714477

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Cells and difusion. Cell structure. Diffusion. Membrane structure. Membrane permeability. Cell walls. Problems. Water. Physical properties. Chemical potential. Central vacuole and chloroplasts. Water potential and plant cells. Chemical potential of ions. Fluxes and diffusion potentials. Active transport. Principles of irreversible thermodynamics. Solute movement across membranes. Light. Wavelength and energy. Absorption of light by molecules. De-excitation. Absorption spectra and action spectra. Photochemistry of photosynthesis. Chlorophyll -- Chemistry and spectra. Other photosynthetic pigments. Electron flow. Bioenergetics. Gibbs free energy. Biological energy currencies. Chloroplast bioenergetics. Energy flow in the biosphere. Temperature. Energy budget -- radiation. Wind -- heat conduction and convection. Latent heat -- transpiration. Soil. Further examples of energy budgets. Leaves and fluxes. Resistances and conductances -- transpiration. Water vapor fluxes accompanying transpiration. CO2 conductances and resistances. CO2 fluxes accompanying photosyntesis. Water use efficiency. Plants and fluxes. Gas fluxes above the leaf canopy. Gas fluxes within plant communities. Soil. Water movement in the xylem and phloem. The soil-plant-atmosphere continuum.

Author : Gaylon S. Campbell
Publisher : Springer Science & Business Media
Page : 172 pages
File Size : 27,62 MB
Release : 2012-12-06
Category : Science
ISBN : 1468499173

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The study of environmental biophysics probably began earlier in man's history than that of any other science. The study of organism-environment interaction provided a key to survival and progress. Systematic study of the science and recording of experimental results goes back many hundreds of years. Ben jamin Franklin, the early American statesman, inventor, printer, and scientist studied conduction, evaporation, and radiation. One of his observations is as follows: My desk on which I now write, and the lock of my desk, are both exposed to the same temperature of the air, and have therefore the same degree of heat or cold; yet if I lay my hand successively on the wood and on the metal, the latter feels much the coldest, not that it is really so, but being a better conductor, it more readily than the wood takes away and draws into itself the fire that was in my skin. 1 Franklin probably was not the first to discover this principle, and certainly was not the last. Modem researchers rediscover this principle frequently in their own work. It is sometimes surprising how slowly progress is made. Progress in environmental biophysics, since the observa tions of Franklin and others, has been mainly in two areas: use of mathematical models to quantify rates of heat and mass transfer and use of the continuity equation that has led to energy budget analyses.

Author : William Kirby Smith
Publisher : UNAM
Page : 442 pages
File Size : 10,53 MB
Release : 2009
Category : Science
ISBN : 0578004216

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Park S. Nobel pioneered the coupling of cellular physical chemistry with plant physiology, providing a sound physicochemical interpretation of the laws of diffusion to a rapidly expanding field of plant physiological ecology. His classical textbook is the only one of its kind to provide an extensive array of quantitative problems and solutions in the field of plant biophysics and ecophysiology, extending from the molecular to the ecological level. In this festschrift, former graduate students and postdocs, as well as colleagues of Prof. Nobel present a series of reviews that include scales from sub-cellular to global, and topics that range from desert succulent biology to the physiology of alpine plants, encompassing basic research and applications in agronomy and conservation biology. This state-of-the-field survey provides current and useful information for professionals and graduate students, while illustrating the broad span of the influence that Nobel's career has had on modern ecophysiology.

Author : Thomas G. Hallam
Publisher : Springer Science & Business Media
Page : 455 pages
File Size : 26,74 MB
Release : 2012-12-06
Category : Mathematics
ISBN : 3642698883

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There isprobably no more appropriate location to hold a course on mathematical ecology than Italy, the countryofVito Volterra, a founding father ofthe subject. The Trieste 1982Autumn Course on Mathematical Ecology consisted of four weeksofvery concentrated scholasticism and aestheticism. The first weeks were devoted to fundamentals and principles ofmathematicalecology. A nucleusofthe material from the lectures presented during this period constitutes this book. The final week and a half of the Course was apportioned to the Trieste Research Conference on Mathematical Ecology whose proceedings have been published as Volume 54, Lecture Notes in Biomathematics, Springer-Verlag. The objectivesofthe first portionofthe course wereambitious and, probably, unattainable. Basic principles of the areas of physiological, population, com munitY, and ecosystem ecology that have solid ecological and mathematical foundations were to be presented. Classical terminology was to be introduced, important fundamental topics were to be developed, some past and some current problems of interest were to be presented, and directions for possible research were to be provided. Due to time constraints, the coverage could not be encyclopedic;many areas covered already have merited treatises of book length. Consequently, preliminary foundation material was covered in some detail, but subject overviewsand area syntheseswerepresented when research frontiers were being discussed. These lecture notes reflect this course philosophy.