Norrocky M.J. (1991) Observations on the ecology, reproduction and growth <strong>of</strong> the burrowing crayfish Fallicambarus (Creaserinus) Fodiens (Decapoda: Cambaridae) in North-central Ohio. American Midland Naturalist, 125, 75-86. Parkyn S.M., Collier K.J. & Hicks B.J. (2002) Growth and population dynamics <strong>of</strong> crayfish Paranephrops planifrons in streams within native forest and pastoral land uses. New Zealand Journal <strong>of</strong> Marine and Freshwater Research, 36, 847-861. Poulson T.L. & Lavoie K.H. (2001) <strong>The</strong> trophic basis <strong>of</strong> subsurface ecosystems. In: Ecosystems <strong>of</strong> the World; Subterranean Ecosystems Vol. 30 (Eds H. Wilkens, D.C. Culver, & W.F. Humphreys), pp. 231-249. New York, New York, USA. Price J.O. & Payne J.F. (1984) Size, age, and population dynamics in an r-selected population <strong>of</strong> Orconectes neglectus chaenodactylus Williams (Decapoda, Cambaridae). Crustaceana, 46, 29-38. R Development Core Team (2008) R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. ISBN 3-900051-07-0, URL http://www.R-project.org. Reynolds J.T. (2002) Growth and reproduction. In: Biology <strong>of</strong> freshwater crayfish (Eds D. Holdich), pp.152-184. Blackwell Science, Oxford, United Kingdom. Scalici M., Chiesa S., Scuderi S., Celauro D. & Gibertini G. (2010) Population structure and dynamics <strong>of</strong> Procambarus clarkii (Girard, 1852) in a Mediterranean brackish wetland (Central Italy). Biological Invasions, 12, 1415-1425. Streever W.J. (1996) Energy economy hypothesis and the troglobitic crayfish Procambarus erythrops in Sim's Sink Cave, Florida. American Midland Naturalist, 135, 357-366. Vogt G. (2012) Ageing and longevity in the Decapoda (Crustacea): A review. Zoologischer Anzeiger, 251, 1-25. Voituron Y., de Fraipont M., Issartel J., Guillaume O. & Clobert J. (2011) Extreme lifespan <strong>of</strong> the human fish (Proteus anguinus): a challenge for ageing mechanisms. Biology Letters, 7, 105-107. Wanamaker A., Heinemeier J., Scourse J., Richardson C., Butler P., Eiriksson J. & Knudsen K. (2008) Very long-lived molluscs confirm 17th century AD tephra-based radiocarbon reservoir ages for north Icelandic shelf waters. Radiocarbon, 50, 399-412. Weingartner D.L. (1977) Production and trophic ecology <strong>of</strong> two crayfish species cohabiting an Indiana cave. PhD <strong>The</strong>sis, Michigan State <strong>University</strong>, East Lansing, Michigan, USA. 91
Whitmore N. & Huryn A.D. (1999) Life history and production <strong>of</strong> Paranephrops zealandicus in a forest stream, with comments about the sustainable harvest <strong>of</strong> a freshwater crayfish. Freshwater Biology, 42, 467-478. Ziuganov V., Miguel E., Neves R.J., Longa A., Fernández C., Amaro R., Beletsky V., Popkovitch E., Kaliuzhin S. & Johnson T. (2000) Life span variation <strong>of</strong> the freshwater pearl shell: a model species for testing longevity mechanisms in animals. AMBIO, 29, 102-105. 92
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THE INFLUENCE OF ENERGY AVAILABILIT
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ABSTRACT Detritus from surface envi
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LIST OF ABBREVIATIONS AND SYMBOLS m
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NC IL ON U.K. VIAT VIE Fig. North C
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AIC K-S Akaike information criterio
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laboratory work and was an excellen
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LIST OF TABLES TABLE 2.1 TABLE 2.2
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LIST OF FIGURES FIGURE 2.1 (a) Box
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FIGURE 4.3 Growth models for Orcone
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chemolithoautotrophy-based systems;
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ecology, 51, 31-53. Gibert J. & Cul
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CHAPTER 2 EFFECTS OF ORGANIC MATTER
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community structure in cave “pits
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communities and how variation in co
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the different source locations was
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of natural-log transformed data (%
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peak in organic matter in Big Mouth
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Figs. 5a, b). The breakdown rate of
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per litter bag. Similarly, Huntsman
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ags was the greater retention of li
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Historically, limited resource inpu
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Culver, D.C. & Pipan, T. (2009) The
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Merritt, R.W., Cummins, K.W. & Berg
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Table 1. Mean (1 S.D.) macroinverte
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Table 2. Mean (±1 S.D.) daily temp
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Figure 1. (a) Box and whisker plot
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Figure 3. Non-metric multidimension
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Figure 5. Box and whisker plot of l
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