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Data from: Prey size diversity hinders biomass trophic transfer and predator size diversity promotes it in planktonic communities

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关键词：: nano-microplankton;functional diversity;2009-2013;predator-prey dynamics;Biodiversity-ecosystem functioning;size diversity;trophic transfer efficiency;Zooplankton;Body Size;plankton;mesozooplankton

DOI：: doi:10.5061/dryad.300k7

摘要：: orly quantified in the field. Here, we examine how the size diversity of prey (nano-microplankton) and predators (mesozooplankton) influence trophic transfer effic

Data from: A test of trophic and functional island biogeography theory with the avifauna of a continental archipelago

负责人：: Ross, Samuel

关键词：: trophic rank community assembly trophic theory phylogeography Ryūkyū archipelago species-area diversity-area Functional diversity

DOI：: doi:10.5061/dryad.54tm887

摘要：: how functional differences among species may lead to non-random community assembly processes and different diversity-area scaling patterns. First, the trophic TIB

Data from: Multi-trophic ?-diversity mediates the effect of environmental gradients on the turnover of multiple ecosystem functions

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关键词：: multi-trophic;Biodiversity-ecosystem functioning;elevation gradient;path analyses;Alpine systems;?-diversity

DOI：: doi:10.5061/dryad.m2579m0

摘要：: ecosystem functions, we do not know yet which components of multi-trophic ?-diversity influence which ecosystem functions. 2. Here, we captured the biodiversity

Data from: Reef fish functional traits evolve fastest at trophic extremes

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关键词：: Trophic ecology;trophic level;Evolution;coral reefs;Diet Breadth

DOI：: doi:10.5061/dryad.7t3d30c

摘要：: Trophic ecology is thought to exert a profound influence on biodiversity, but the specifics of the process are rarely examined at large spatial

Data from: Tree diversity increases robustness of multi-trophic interactions

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关键词：: Diospyros japonica;Tetramorium wroughtonii;Aphis gossypii;tri-trophic;Crematogaster cf. nawai;Tuberculatus radisectuae;Eutrichosiphum tattakanum;Cinnamomum camphora;bottom-up;aphid;Nyssa sinensis;Camponotus vitiosus;Aphis odinae;Camponotus albosparsus;Aphis aurantii;Tuberculatus querceus;Lachnus tropicalis;Pheidole roberti;Tuberculatus castanocallis;Technomyrmex brunneus;Phylloxera castanea;Idesia polycarpa;Tuberculatus indicus;Paraparatrechina sauteri;Siculaphis vittoriensis;Prenolepis shanialena;Pochazia speculum;Machilus leptophylla;Tuberculatus glauca;Cyclobalanopsis glauca;Iridomyrmex anceps;Tapinoma melanocephalum;Castanea henryi;Machilus thunbergii;Neonipponaphis pustulosis;Dilobocondyla fouqueti;Dolichoderus taprobanae;Kerria lacca;Pheidole noda;redundancy;Sapindus saponaria;Hemiptera;Phylloxera querceus;Crematogaster cf. rogenhoferi;Daphniphyllum oldhamii;Mollitrichosiphum tenuicorpus;Cervaphis quercus;Membracidae;Camponotus cf. compressus;Monomorium floricola;Eutrichosiphum radisectuae;Quercus serrata;Machilus grijsii;Melia azedarach;insect-plant interactions;Lithocarpus glaber;Eutrichosiphum sclerophyllum;Tuberculatus capitatus;Nylanderia flavipes;Phoebe bournei;Choerospondias axillaris;Castanopsis fargesii;Tuberculatus stigmatus;Carebara altinoda;Pristomyrmex punctatus;Celtis biondii;Camponotus pseudoirritans;Polyrhachis dives;Manglietia yuyuanensis;Castanopsis sclerophylla;Elaeocarpus chinensis;insect;Ailanthus altissima;Eutrichosiphum pasaniae;Elaeocarpus glabripetalus;stability;Betacallis querciphaga;Formicidae;Elaeocarpus japonicus;2011-2014;tree;Acer davidii;Castanopsis eyrei;Tuberculatus japonicus;Ochetellus glaber;BEF-China;Eutrichosiphum heterotrichum;Quercus phillyreoides;Paratrechina longicornis;Lepisiota cf. capensis;Quercus fabri;Schima superba;Myzus persicae;Aphis citricidus;Quercus acutissima;Prenolepis naoroji;Cyclobalanopsis myrsinaefolia;coccid;Triadica cochinchinensis;Castanopsis carlesii;biodiversity;ecosystem functioning;Meliosma flexuosa;ant;Triadica sebifera;Rhus chinensis;Diphyllaphis quercus;Pochazia obapicula;Technomyrmex obscurior;Alniphyllum fortunei;Greenidea pallidipes;Liquidambar formosana;Interaction;Tuberculatus ceroerythros;Betula luminifera;Koelreuteria bipinnata

DOI：: doi:10.5061/dryad.847km00

摘要：: of multi-trophic community diversity and interaction robustness in forests.

Data from: The relative importance of plant intraspecific diversity in structuring arthropod communities: a meta-analysis

负责人：: Koricheva, Julia

关键词：: biodiversity associational resistance community genetics genetic diversity herbivory natural enemies plant-insect interactions tritrophic interactions

DOI：: doi:10.5061/dryad.mp1bk57

摘要：: t of plant species diversity. 6. Our results suggest that plant genetic diversity has significant effects on the diversity of arthropods across several trophic leve

Data from: Spatial insurance in multi-trophic metacommunities

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关键词：: trophic interactions;environmental change;Dispersal;metacommunity

DOI：: doi:10.5061/dryad.360k8v0

摘要：: ation on phytoplankton diversity mid-experiment, but had no effect on the diversity of zooplankton and bacteria. Likewise, trophic groups differed in whether dispersal facilitated

Data from: Congruence, but no cascade - pelagic biodiversity across 3 trophic levels in Nordic lakes

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关键词：: biodiversity;phytoplankton;Zooplankton;Fish

DOI：: doi:10.5061/dryad.7m0cfxprd

摘要：: km longitudinal transect. The fraction of the total diversity variation explained by local environment alone was small for all trophic levels while a substantial

Data from: Mapping the imprint of biotic interactions on ?-diversity

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关键词：: partial correlation networks;interaction network;graphical model;graphical lasso;meta-communities;Holocene;?-diversity

DOI：: doi:10.5061/dryad.5b58400

摘要：: Investigating how trophic interactions influence the ?-diversity of meta-communities is of paramount importance to understanding the pro

Data from: Tempo of trophic evolution and its impact on mammalian diversification

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关键词：: mammal;Macroevolution;Mammalia;diet;diversification;Holocene to Cretaceous

DOI：: doi:10.5061/dryad.vr28vf67

摘要：: rate (the cumulative effect of speciation and extinction), differs significantly among living mammals, depending upon trophic strategy. Herbivores diversify fastest, carnivores

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Data from: Prey size diversity hinders biomass trophic transfer and predator size diversity promotes it in planktonic communities

Data from: A test of trophic and functional island biogeography theory with the avifauna of a continental archipelago

Data from: Multi-trophic ?-diversity mediates the effect of environmental gradients on the turnover of multiple ecosystem functions

Data from: Reef fish functional traits evolve fastest at trophic extremes

Data from: Tree diversity increases robustness of multi-trophic interactions

Data from: The relative importance of plant intraspecific diversity in structuring arthropod communities: a meta-analysis

Data from: Spatial insurance in multi-trophic metacommunities

Data from: Congruence, but no cascade - pelagic biodiversity across 3 trophic levels in Nordic lakes

Data from: Mapping the imprint of biotic interactions on ?-diversity

Data from: Tempo of trophic evolution and its impact on mammalian diversification

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