Complexity in quantitative food webs

C. Banasek-Richter; L.F. Bersier; M.F. Cattin; R. Baltensperger; J.P. Gabriel; Y. Merz; R.E. Ulanowicz; A.F. Tavares; D.D. Williams; P.C. de Ruiter; K.O. Winemiller; R.E. Naisbit

doi:10.1890/08-2207.1

Complexity in quantitative food webs

C. Banasek-Richter, L.F. Bersier, M.F. Cattin, R. Baltensperger, J.P. Gabriel, Y. Merz, R.E. Ulanowicz, A.F. Tavares, D.D. Williams, P.C. de Ruiter, K.O. Winemiller, R.E. Naisbit

Research output: Contribution to journal › Article › Academic › peer-review

106 Citations (Scopus)

Abstract

Food webs depict who eats whom in communities. Ecologists have examined statistical metrics and other properties of food webs, but mainly due to the uneven quality of the data, the results have proved controversial. The qualitative data on which those efforts rested treat trophic interactions as present or absent and disregard potentially huge variation in their magnitude, an approach similar to analyzing traffic without differentiating between highways and side roads. More appropriate data are now available and were used here to analyze the relationship between trophic complexity and diversity in 59 quantitative food webs from seven studies (14-202 species) based on recently developed quantitative descriptors. Our results shed new light on food-web structure. First, webs are much simpler when considered quantitatively, and link density exhibits scale invariance or weak dependence on food-web size. Second, the "constant connectance'' hypothesis is not supported: connectance decreases with web size in both qualitative and quantitative data. Complexity has occupied a central role in the discussion of food-web stability, and we explore the implications for this debate. Our findings indicate that larger webs are more richly endowed with the weak trophic interactions that recent theories show to be responsible for food-web stability.

Original language	English
Pages (from-to)	1470-1477
Journal	Ecology
Volume	90
Issue number	6
DOIs	https://doi.org/10.1890/08-2207.1
Publication status	Published - 2009

Keywords

trophic interactions
community stability
sampling effort
scale
networks
descriptors
connectance
adaptation
ecosystems
patterns

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10.1890/08-2207.1

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title = "Complexity in quantitative food webs",

abstract = "Food webs depict who eats whom in communities. Ecologists have examined statistical metrics and other properties of food webs, but mainly due to the uneven quality of the data, the results have proved controversial. The qualitative data on which those efforts rested treat trophic interactions as present or absent and disregard potentially huge variation in their magnitude, an approach similar to analyzing traffic without differentiating between highways and side roads. More appropriate data are now available and were used here to analyze the relationship between trophic complexity and diversity in 59 quantitative food webs from seven studies (14-202 species) based on recently developed quantitative descriptors. Our results shed new light on food-web structure. First, webs are much simpler when considered quantitatively, and link density exhibits scale invariance or weak dependence on food-web size. Second, the {"}constant connectance'' hypothesis is not supported: connectance decreases with web size in both qualitative and quantitative data. Complexity has occupied a central role in the discussion of food-web stability, and we explore the implications for this debate. Our findings indicate that larger webs are more richly endowed with the weak trophic interactions that recent theories show to be responsible for food-web stability.",

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AU - Banasek-Richter, C.

AU - Bersier, L.F.

AU - Cattin, M.F.

AU - Baltensperger, R.

AU - Gabriel, J.P.

AU - Merz, Y.

AU - Ulanowicz, R.E.

AU - Tavares, A.F.

AU - Williams, D.D.

AU - de Ruiter, P.C.

AU - Winemiller, K.O.

AU - Naisbit, R.E.

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PY - 2009

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N2 - Food webs depict who eats whom in communities. Ecologists have examined statistical metrics and other properties of food webs, but mainly due to the uneven quality of the data, the results have proved controversial. The qualitative data on which those efforts rested treat trophic interactions as present or absent and disregard potentially huge variation in their magnitude, an approach similar to analyzing traffic without differentiating between highways and side roads. More appropriate data are now available and were used here to analyze the relationship between trophic complexity and diversity in 59 quantitative food webs from seven studies (14-202 species) based on recently developed quantitative descriptors. Our results shed new light on food-web structure. First, webs are much simpler when considered quantitatively, and link density exhibits scale invariance or weak dependence on food-web size. Second, the "constant connectance'' hypothesis is not supported: connectance decreases with web size in both qualitative and quantitative data. Complexity has occupied a central role in the discussion of food-web stability, and we explore the implications for this debate. Our findings indicate that larger webs are more richly endowed with the weak trophic interactions that recent theories show to be responsible for food-web stability.

AB - Food webs depict who eats whom in communities. Ecologists have examined statistical metrics and other properties of food webs, but mainly due to the uneven quality of the data, the results have proved controversial. The qualitative data on which those efforts rested treat trophic interactions as present or absent and disregard potentially huge variation in their magnitude, an approach similar to analyzing traffic without differentiating between highways and side roads. More appropriate data are now available and were used here to analyze the relationship between trophic complexity and diversity in 59 quantitative food webs from seven studies (14-202 species) based on recently developed quantitative descriptors. Our results shed new light on food-web structure. First, webs are much simpler when considered quantitatively, and link density exhibits scale invariance or weak dependence on food-web size. Second, the "constant connectance'' hypothesis is not supported: connectance decreases with web size in both qualitative and quantitative data. Complexity has occupied a central role in the discussion of food-web stability, and we explore the implications for this debate. Our findings indicate that larger webs are more richly endowed with the weak trophic interactions that recent theories show to be responsible for food-web stability.

KW - trophic interactions

KW - community stability

KW - sampling effort

KW - scale

KW - networks

KW - descriptors

KW - connectance

KW - adaptation

KW - ecosystems

KW - patterns

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DO - 10.1890/08-2207.1

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SN - 0012-9658

VL - 90

SP - 1470

EP - 1477

JO - Ecology

JF - Ecology

IS - 6

ER -

Complexity in quantitative food webs

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Keywords

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