Abstract
The central rôle of energy in all life processes has led to the development of numerous hypotheses, conjectures and theories on the relationships between thermodynamics and ecological processes. In this paper we examine the theoretical and empirical support for these developments, and in particular for the widely published set of thermodynamic conjectures developed by H.T. Odum, in which the maximum power principle is put forward as a generic feature of evolution in ecosystems. Although they are widely used, we argue that many of the ecological studies that have adopted the ideas encapsulated in Odum's work have done so without being aware of some of the fundamental problems underlying this approach. We discuss alternative ways in which a general available-work concept could be constructed for use as a numeraire in an energy-centered ecological theory or paradigm. In so doing, we examine what is meant by material accessibility and energy stocks and flows with respect to traditional food web and food chain theories, and relate these to results from the evolutionary dynamics of ecosystems. We conclude that the various forms and uses of energy bound up in essential ecosystem processes present a formidable obstacle to obtaining an operational definition of a general, aggregated available-work concept, a prerequisite for the systems approach of Odum and others. We also show that the prototypical derivations of the maximum power principle, and its interpretation, are contradicted on many scales both by empirical data and models, thereby invalidating the maximum power principle as a general principle of ecological evolution. The conclusions point to the fundamental problem of trying to describe ecosystems in a framework which has a one-dimensional currency.
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References
Ahrendts J (1980) Reference states. Energy 5:667–677
Andresen B (1983) Finite-time thermodynamics. Doctoral Thesis, University of Copenhagen
Ashby WR (1973) Design for a brain. Wiley, New York
Baird D, McGlade JM, Ulanowicz R (1991) The comparative ecology of six marine ecosystems. Phil Trans Soc Lond B 333:15–29
Battley EH (1987) Energetics of microbial growth. Wiley, New York
Bertalanffy L von (1968) General system theory. Braziller, New York
Blaxter K (1989) Energy metabolism in animals and man. Cambridge University Press, Cambridge
Brooks DR, Wiley EO (1988) Evolution as entropy: toward a unified theory of biology, 2nd edn. University of Chicago Press, Chicago
Calow P (1977) Ecology, evolution, and energetics: a study in metabolic adaption. Adv Ecol Res 10:1–62
Cherret JM (1989) Key concepts, the result of a survey of our members' opinion. In: Cherret JM (ed) Ecological concepts. Blackwell, Oxford, pp 1–16
Clutton-Brock TH (ed) (1988) Reproductive success. University of Chicago Press, Chicago
Curzon FL, Ahlborn B (1975) Efficiency of a Carnot engine at maximum power output. Am J Phys 43:22–24
Denbigh K (1981) The principles of chemical equilibrium, 4th edn. Cambridge University Press, Cambridge
Elton C (1927) Animal ecology. Macmillan, New York
Eriksson K-E, Lindgren K, Månsson BÅ (1987) Structure, context, complexity, organization — physical aspects of information and value. World Scientific, Singapore
Fenchel T (1974) Intrinsic rate of natural increase: the relationship with body size. Oecologia 14:317–326
Fenchel T (1987) Ecology — potentials and limitations. Ecology Institute, Oldendorf/Luhe, Germany
Gallo WLR, Milanez LF (1990) Choice of a reference state for exergetic analysis. Energy 15:113–121
Gallucci VF (1973) On the principles of thermodynamics in ecology. Annu Rev Ecol Syst 4:329–357
Gates DM (1980) Biophysical ecology. Springer, Berlin Heidelberg New York
Gause GF (1934) The struggle for existence. Williams and Wilkins, Baltimore. Reprinted (1964) by Hafner Press, New York
Grinnell J (1917) The niche-relationship of the California Thrasher. Auk 34:427–433
Groot SR de (1952) Thermodynamics of irreversible processes. North-Holland, Amsterdam
Groot SR de, Mazur P (1962) Non-equilibrium thermodynamics. North-Holland, Amsterdam. Republished (1984) by Dover, New York
Haldane JBS (1928) On being the right size. In: Shapely H, Raffort S, Wright H (eds) A treasury of science. Harper, New York, pp 321–325
Hemmingsen AM (1960) Energy metabolism as related to body size and respiratory surfaces. Reports of the Steno Memorial Hospital, Copenhagen, Vol IX Part II: 7–10
Hennig W (1966) Phylogenetic systematics. University of Illinois Press, Urbana
Hogg T, Huberman BA McGlade JM (1989) The stability of ecosystems. Proc R Soc Lond B237:43–51
Hutchinson GE, (1948) Circular causal systems in ecology. Ann N Y Acad Sci 50:221–246
Hutchinson GE (1957) Concluding remarks. Cold Spring Harbor Symp Quant Biol 22:415–427
Johnson L (1981) The thermodynamic origin of ecosystems. Can J Fish Aquat Sci 38:571–590
Johnson PW, Sieburth JMcN (1979) Chroococcoid cyanobacteria at sea: a ubiquitous and diverse phototrophic biomass. Limnol Oceanogr 24:928–935
Karlsson S (1982) The exergy of incoherent electromagnetic radiation. Phys Scr 26:329–332
Katchalsky A, Curran PF (1965) Nonequilibrium thermodynamics in biophysics, Harvard University Press, Cambridge, Mass
Kleiber M (1961) The fire of life: an introduction to animal energetics. Wiley, New York
Krebs JR, Houston AI (1989) Optimization in ecology. In: Cherret JM (ed) Ecological concepts. Blackwell, Oxford, pp 309–338
Kuhn T (1962) The structure of scientific revolutions. University of Chicago Press, Chicago
Lehninger AL (1971) Bioenergetics, 2nd edn. Benjamin, New York
Liebig J (1855) Principles of agricultural chemistry with special reference to the late researches made in England. Walton and Maberly, London
Lindeman RL (1942) The trophic-dynamic aspect of ecology. Ecology 23:399–418
Lotka AJ (1922a) Contribution to the energetics of evolution. Proc Natl Acad Sci 8:147–150
Lotka AJ (1922b) Natural selection as a physical principle. Proc Natl Acad Sci 8:151–154
Lotka AJ (1924) Elements of physical biology. Reprinted (1956) as Elements of mathematical biology. Dover, New York
MacArthur RH, Wilson EO (1967) The theory of island biogeography. Princeton University Press, Princeton
Månsson BÅ (1985) Entropy production in oscillating chemical systems. Z Naturforsch 40a:877–885
Margalef R (1963) On certain unifying principles in ecology. Am Nat 97:357–374
Miller DH (1981) Energy at the surface of the earth-an introduction to the energetics of ecosystems. Academic Press, New York
Moran MJ (1982) Availability analysis: a guide to efficient energy use. Prentice-Hall, Englewood Cliffs, NJ
Morowitz HJ (1968) Energy flow in biology — biological organization as a problem in thermal physics. Academic Press, London
Morris DR, Szargut J (1986) Standard chemical exergy of some elements and compounds on the planet Earth. Energy 11:733–755
Odum EP (1953) Fundamentals of ecology. Saunders, Philadelphia (further editions in 1959 and 1971)
Odum EP (1969) The strategy of ecosystem development. Science 164:262–270
Odum EP (1975) Ecology: the link between the natural and social sciences, 2nd edn. Holt, Rinehart and Winston, New York
Odum EP (1977) The emergence of ecology as a new integrative discipline. Science 195:1289–1293
Odum HT (1956) Efficiencies, size of organisms, and community structure. Ecology 37:592–597
Odum HT (1957) Trophic structure and productivity of Silver Springs, Florida. Ecol Monogr 27:55–112
Odum HT (1971) Environment, power and society. Wiley-Interscience, New York
Odum HT (1983) Systems ecology. Wiley, New York
Odum HT (1987) Living with complexity. In: Crafoord Lectures. The Royal Swedish Academy of Sciences, Stockholm
Odum HT (1988) Self-organization, transformity, and information. Science 242:1132–1139
Odum HT, Pinkerton R (1955) Time's speed regulator: the optimum efficiency for maximum power in physical and biological systems. Am Sci 43:331–343
O'Neill RV, DeAngelis DL, Waide JB, Allen TFH (1986) A hierarchical concept of ecosystems. Princeton University Press, Princeton
O'Neill RV, DeAngelis DL, Pastor JJ, Jackson BJ, Post WM (1989) Multiple nutrient limitations in ecological models. Ecol Model 46:147–163
Paine RT (1980) Food webs: linkage, interaction strength and community infrastructure. J Anim Ecol 49:667–685
Peters RH (1983) The ecological implications of body size. Cambridge University Press, Cambridge
Pianka ER (1974) Evolutionary ecology. Harper and Row, New York
Pimm SL, Kitching RL (1987) The determinants of food chain lengths. Oikos 50:302–307
Platt T (1985) Structure of the marine ecosystem: its allometric basis. In: Ulanowicz RE, Platt T (eds) Ecosystem theory for biological oceanography. Can Bull Fish Aquat Sci 213:55–64
Platt T, Silvert W (1981) Ecology, physiology, allometry and dimensionality. J Theor Biol 93:855–860
Platt T, Subba Rao DW, Irwin B (1983) Photosynthesis of picoplankton in the oligotrophic ocean. Nature 300:702–704
Pomeroy LR (1974) The ocean's food web, a changing paradigm. Bioscience 24:499–504
Pomeroy LR, Alberts JJ (1988) Problems and challenges in ecosystem analysis. In: Pomeroy LR, Alberts JJ (eds) Concepts of ecosystems ecology. Springer, New York Berlin Heidelberg, pp 317–323
Porter WP, Gates DM (1969) Thermodynamic equilibria of animals with environment. Ecol Monogr 39:227–244
Rand DA, Wilson HB, McGlade JM (1992) Dynamics and evolution: evolutionary stable attractors, invasion exponents and phenotype dynamics. Warwick University Preprints 53/1992
Rant Z (1956) Exergie, ein neues Wort für “technische Arbeitsfähigkeit”. Forsch Geb Ingenieurwes 22:36–37
Reif F (1965) Fundamentals of statistical and thermal physics. McGraw-Hill, Tokyo
Roughgarden J (1972) Evolution of niche width. Am Nat 106:638–718
Roughgarden J (1974) Niche width: biogeographic patterns among Anolis lizard populations. Am Nat 108:429–442
Roughgarden J (1979) Theory of population genetics and evolutionary ecology: an introduction. MacMillan, New York
Schoener T (1989) The ecological niche. In: Cherret JM (ed) Ecological concepts. Blackwell, Oxford, pp 79–113
Sheldon RW, Prakash A, Sutcliffe WH (1972) The size distribution of particles in the ocean. J Fish Res Board Can 34:2344–2353
Slobodkin LB (1960) Ecological energy relationships at the population level. Am Nat 94:213–236
Slobodkin LB (1962) Energy in animal ecology. Adv Ecol Res 1:69–101
Smerage G (1976) Matter and energy flows in biological and ecological systems. J Theor Biol 57:203–223
Sussman MV (1980) Steady-flow availability and the standard chemical availability. Energy 5:793–802
Szargut J (1980) International progress in second law analysis. Energy 5:709–718
Taylor PJ (1988) Technocratic optimism, H.T. Odum, and the partial transformation of ecological metaphor after World War II. J Hist Biol 21:213–244
Tilman D (1982) Resource competition and community structure. Princeton University Press, Princeton
Ulanowicz RE (1986) Growth and development, ecosystems phenomenology. Springer, New York Berlin Heidelberg
Waring RH (1989) Ecosystems: fluxes of matter and energy. In: Cherret JM (ed) Ecological concepts. Blackwell, Oxford, pp 17–41
Westerhoff HV, Dam K van (1987) Thermodynamics and control of biological free-energy transduction. Elsevier, Amsterdam
Westerhoff HV, Hellingwerf KJ, Dam K van (1983) Thermodynamic efficiency of microbial growth is low but optimal for maximal growth rate. Proc Nat Acad Sci 80:305–309
Whittaker RH, Levin SA (eds) (1975) Niche: theory and applications. Dowden, Hutchinson and Ross, New York
Wicken JS (1985) Thermodynamics and the conceptual structure of evolutionary theory. J Theor Biol 117:363–383
Wiegert RG (1988) The past, present, and future of ecological energetics. In: Pomeroy LR, Alberts JJ (eds) Concepts of ecosystems ecology. Springer, New York Berlin Heidelberg, pp 29–55
Woods LC (1975) The thermodynamics of fluid systems. Oxford University Press, Oxford
Woodward FI (1990) From ecosystems to genes: the importance of shade tolerance. Trends Ecol Evol 5:111–115
Yodzis P (1989) Introduction to theoretical ecology. Harper & Row, New York
Zotin AI (1985) Thermodynamics and growth of organisms in ecosystems. In: Ulanowicz RE, Platt T (eds) Ecosystem theory for biological oceanography. Can Bull Fish Aquat Sci 213:27–37
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Månsson, B.Å., McGlade, J.M. Ecology, thermodynamics and H.T. Odum's conjectures. Oecologia 93, 582–596 (1993). https://doi.org/10.1007/BF00328969
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DOI: https://doi.org/10.1007/BF00328969