AVAILABLE ENERGY AND SPECIES DIVERSITY: THEORY AND EXPERIMENTS WITH BEES (COMMUNITIES, FLOWERS, FORAGING).

A general biogeographic theory of insular species diversity, species-energy theory, is produced by replacing area in species-area models with a measure of available energy. Islands with more available energy support larger populations, which have lower extinction rates. Given similar immigration rat...

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Main Author: WRIGHT, DAVID HAMILTON.
Format: Thesis
Language:English
Published: The University of Arizona. 1984
Subjects:
Bees > Speciation
Ecological genetics
Greenland
Online Access:http://hdl.handle.net/10150/187808
id ftunivarizona:oai:repository.arizona.edu:10150/187808
record_format openpolar
spelling ftunivarizona:oai:repository.arizona.edu:10150/187808 2023-05-15T16:30:28+02:00 AVAILABLE ENERGY AND SPECIES DIVERSITY: THEORY AND EXPERIMENTS WITH BEES (COMMUNITIES, FLOWERS, FORAGING). WRIGHT, DAVID HAMILTON. 1984 http://hdl.handle.net/10150/187808 en eng The University of Arizona. http://hdl.handle.net/10150/187808 693345251 8500480 Copyright © is held by the author. Digital access to this material is made possible by the University Libraries, University of Arizona. Further transmission, reproduction or presentation (such as public display or performance) of protected items is prohibited except with permission of the author. Bees -- Speciation Ecological genetics text Dissertation-Reproduction (electronic) 1984 ftunivarizona 2020-06-14T08:03:52Z A general biogeographic theory of insular species diversity, species-energy theory, is produced by replacing area in species-area models with a measure of available energy. Islands with more available energy support larger populations, which have lower extinction rates. Given similar immigration rates, islands with greater available energy are therefore expected to support greater equilibrium numbers of species. Assuming that total population size is proportional to energy supply, and that species-abundance distributions are lognormal and of similar form, the species-energy relationship is approximated by S = kEᶻ. Species-energy theory explains 70-80% of the variation in species number of angiosperms and of birds on such widely varying islands as Greenland and Jamaica. The effects of energy on the structure of a subalpine bee community in Colorado were investigated. As available nector declined, during mornings and over the season, foraging profitability for Bombus appositus (Hymenoptera: Apidae) decreased. This change was manifested by increased foraging trip durations: nector loads did not change. Total colony profits increased as colonies grew over the season, but profit relative to colony size declined, due to reduced profitability of individual foraging trips. These results support the hypothesis of resource limitation in this species. Assemblages of bees foraging on patches of flowers showed effects of energy availability on species composition and dynamics. Bees foraging in enriched patches had lower departure rates than bees in control patches, and, consequently, increased equilibrium numbers of individuals and species present per patch. Both behavioral and mechanical factors influenced departure rates. A species-specific arrival-departure rate model satisfactorily described the foraging assemblages and their response to enrichment. Experiments performed on 2 species of flowers with different corolla tube lengths demonstrated that bee species respond differently to resources of unequal availability, necessitating a species-level approach. Analogies with island systems are discussed. Energy is important to communities in general and bees in particular on a variety of scales. By implication, human resource diversion from natural ecosystems may have profound impacts on global diversity and extinction. Thesis Greenland The University of Arizona: UA Campus Repository Greenland
institution Open Polar
collection The University of Arizona: UA Campus Repository
op_collection_id ftunivarizona
language English
topic Bees -- Speciation
Ecological genetics
spellingShingle Bees -- Speciation
Ecological genetics
WRIGHT, DAVID HAMILTON.
AVAILABLE ENERGY AND SPECIES DIVERSITY: THEORY AND EXPERIMENTS WITH BEES (COMMUNITIES, FLOWERS, FORAGING).
topic_facet Bees -- Speciation
Ecological genetics
description A general biogeographic theory of insular species diversity, species-energy theory, is produced by replacing area in species-area models with a measure of available energy. Islands with more available energy support larger populations, which have lower extinction rates. Given similar immigration rates, islands with greater available energy are therefore expected to support greater equilibrium numbers of species. Assuming that total population size is proportional to energy supply, and that species-abundance distributions are lognormal and of similar form, the species-energy relationship is approximated by S = kEᶻ. Species-energy theory explains 70-80% of the variation in species number of angiosperms and of birds on such widely varying islands as Greenland and Jamaica. The effects of energy on the structure of a subalpine bee community in Colorado were investigated. As available nector declined, during mornings and over the season, foraging profitability for Bombus appositus (Hymenoptera: Apidae) decreased. This change was manifested by increased foraging trip durations: nector loads did not change. Total colony profits increased as colonies grew over the season, but profit relative to colony size declined, due to reduced profitability of individual foraging trips. These results support the hypothesis of resource limitation in this species. Assemblages of bees foraging on patches of flowers showed effects of energy availability on species composition and dynamics. Bees foraging in enriched patches had lower departure rates than bees in control patches, and, consequently, increased equilibrium numbers of individuals and species present per patch. Both behavioral and mechanical factors influenced departure rates. A species-specific arrival-departure rate model satisfactorily described the foraging assemblages and their response to enrichment. Experiments performed on 2 species of flowers with different corolla tube lengths demonstrated that bee species respond differently to resources of unequal availability, necessitating a species-level approach. Analogies with island systems are discussed. Energy is important to communities in general and bees in particular on a variety of scales. By implication, human resource diversion from natural ecosystems may have profound impacts on global diversity and extinction.
format Thesis
author WRIGHT, DAVID HAMILTON.
author_facet WRIGHT, DAVID HAMILTON.
author_sort WRIGHT, DAVID HAMILTON.
title AVAILABLE ENERGY AND SPECIES DIVERSITY: THEORY AND EXPERIMENTS WITH BEES (COMMUNITIES, FLOWERS, FORAGING).
title_short AVAILABLE ENERGY AND SPECIES DIVERSITY: THEORY AND EXPERIMENTS WITH BEES (COMMUNITIES, FLOWERS, FORAGING).
title_full AVAILABLE ENERGY AND SPECIES DIVERSITY: THEORY AND EXPERIMENTS WITH BEES (COMMUNITIES, FLOWERS, FORAGING).
title_fullStr AVAILABLE ENERGY AND SPECIES DIVERSITY: THEORY AND EXPERIMENTS WITH BEES (COMMUNITIES, FLOWERS, FORAGING).
title_full_unstemmed AVAILABLE ENERGY AND SPECIES DIVERSITY: THEORY AND EXPERIMENTS WITH BEES (COMMUNITIES, FLOWERS, FORAGING).
title_sort available energy and species diversity: theory and experiments with bees (communities, flowers, foraging).
publisher The University of Arizona.
publishDate 1984
url http://hdl.handle.net/10150/187808
geographic Greenland
geographic_facet Greenland
genre Greenland
genre_facet Greenland
op_relation http://hdl.handle.net/10150/187808
693345251
8500480
op_rights Copyright © is held by the author. Digital access to this material is made possible by the University Libraries, University of Arizona. Further transmission, reproduction or presentation (such as public display or performance) of protected items is prohibited except with permission of the author.
_version_ 1766020189526163456

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