Best practices for use of stable isotope mixing models in food-web studies
about
Trophic Niche Differentiation in Rodents and Marsupials Revealed by Stable IsotopesReappraisal of the Trophic Ecology of One of the World's Most Threatened Spheniscids, the African Penguin.Spatial and temporal variation of an ice-adapted predator's feeding ecology in a changing Arctic marine ecosystem.Selecting the best stable isotope mixing model to estimate grizzly bear diets in the Greater Yellowstone Ecosystem.Estimating δ15N fractionation and adjusting the lipid correction equation using Southern African freshwater fishes.Diet-to-female and female-to-pup isotopic discrimination in South American sea lions.Not all jellyfish are equal: isotopic evidence for inter- and intraspecific variation in jellyfish trophic ecologyMethods to identify the prey of invertebrate predators in terrestrial field studiesTrophic ecology of sea urchins in coral-rocky reef systems, Ecuador.Beyond carbon and nitrogen: guidelines for estimating three-dimensional isotopic niche space.Non-reliance of metazoans on stromatolite-forming microbial mats as a food resource.Trophic behaviour of juvenile reef fishes inhabiting interlinked mangrove-seagrass habitats in offshore mangrove islets.Simultaneous estimation of diet composition and calibration coefficients with fatty acid signature data.Ocean acidification as a driver of community simplification via the collapse of higher-order and rise of lower-order consumersSpecialized morphology corresponds to a generalist diet: linking form and function in smashing mantis shrimp crustaceans.Variation in stable-isotope ratios between fin and muscle tissues can alter assessment of resource use in tropical river fishes.Stable isotope signatures and trophic-step fractionation factors of fish tissues collected as non-lethal surrogates of dorsal muscle.Ecosystem functioning approach applied to a large contaminated coastal site: the study case of the Mar Piccolo of Taranto (Ionian Sea).Hydrothermal activity, functional diversity and chemoautotrophy are major drivers of seafloor carbon cycling.More than a corridor: use of a main stem stream as supplemental foraging habitat by a brook trout metapopulation.Reliance on deep soil water in the tree species Argania spinosa.Elemental turnover rates and trophic discrimination in juvenile Lebranche mullet Mugil liza under experimental conditions.The role of feeding morphology and competition in governing the diet breadth of sympatric stomatopod crustaceans.Annual mass drownings of the Serengeti wildebeest migration influence nutrient cycling and storage in the Mara River.Blood-specific isotopic discrimination factors in the Magellanic penguin (Spheniscus magellanicus).Isotopic variation in five species of stream fishes under the influence of different land uses.Grazer responses to variable macroalgal resource conditions facilitate habitat structuring.Trophic relationship between the invasive parasitic copepod Mytilicola orientalis and its native blue mussel (Mytilus edulis) host.Resource Use of an Aquacultured Oyster (Crassostrea gigas) in the Reverse Estuary Bahía San Quintín, Baja California, MéxicoComparative isotopic natural history of two native passerines (Troglodytes cobbiandCinclodes antarcticus) and the invasive rats (Rattus norvegicus) that extirpate themMeasuring the realized niches of animals using stable isotopes: from rats to bearsTrophic interactions in an austral temperate ephemeral pond inferred using stable isotope analysisHead morphology and piscivory of European eels,Anguilla anguilla, predict their probability of infection by the invasive parasitic nematodeAnguillicoloides crassusExpanding the Isotopic Toolbox: Applications of Hydrogen and Oxygen Stable Isotope Ratios to Food Web StudiesVariable niche size of the giant mangrove whelk Terebralia palustris (Linnaeus, 1767) in a subtropical estuarySIDER: an R package for predicting trophic discrimination factors of consumers based on their ecology and phylogenetic relatednessDepth gradient in the resource use of a fish community from a semi-enclosed seaUsing behavioral and stable isotope data to quantify rare dietary plasticity in a temperate batPlant source water apportionment using stable isotopes: A comparison of simple linear, two-compartment mixing model approachesESTRATEGIAS HUMANAS, ESTABILIDAD Y CAMBIO EN LA FRONTERA AGRÍCOLA SUR AMERICANA
P2860
Q28601101-E880753C-44E1-41AB-9DBA-3830ED5DC263Q30376978-788B53F5-D477-47E1-901B-92DAB563B630Q30982644-B07EC490-743F-4146-866F-B834C146D6F0Q33664834-736902B9-CB82-4C19-9C95-30DCD0B47CC5Q33725084-AE0AFABD-02D1-40A7-9A0C-3C81F25F7540Q35714614-31E9413C-CCCC-4A36-90DA-D36594145368Q35897430-5BD40A07-3912-48C6-B531-5F577A6BC4EFQ36319147-45895659-A255-425A-AF69-A7256D634A4AQ36525169-4E837A75-9B9E-4AE8-B490-6A57700156B9Q36805766-3AF68DEC-F7BD-4716-8426-A9BADDFEA35AQ37644387-EFB7120B-FBA0-4C93-AA6A-4B3DE047A383Q38390316-72772E6D-3071-4E3F-9EB0-74D47525650AQ38598750-ED1F0062-8684-4C64-A95E-842B2327F0CEQ38667759-CD691843-8087-4751-BE4D-5AA84B72D4DBQ38971586-1234C2C0-2C0A-4C31-9543-39CF23B4542BQ39059510-868817B3-8D01-41CD-82A4-1988E1DA245EQ40695047-24E6C63B-8F7B-42BE-9012-EFE214ADE2CFQ40750727-63E18F55-68AB-4379-980A-13D7FD22C5FFQ41696680-CB4E0EFF-1F9F-4A6E-BAEC-91BAB08D5FA0Q45036787-775DA3D3-2C5E-4399-8267-50733DE37D79Q46166782-B05C7CA8-A420-4637-8192-70326F470FCEQ46307260-697BE2BE-C1AE-40E8-8ADF-F097AD4A976EQ46314619-C9B0D017-1684-4EAC-AC67-2554AFC6DD98Q46347652-0D795AC4-2CAC-4BC0-9D34-B1E3A262545DQ46508162-09A14C91-20D6-4228-9ADA-05B201B30664Q46696626-8CE826F3-83E3-4FA6-B1FC-1C0D90CEC3F4Q48094403-F9A6BBA9-94F7-448B-989A-37AFC5F2AE4BQ49570333-BFCFF08F-9139-4882-8187-399468E193BEQ54966429-0D6B64D5-3710-4460-9DC5-DC5143BF0ED1Q56383700-3AF7AE11-2445-4EA1-BE17-5EA055CC166AQ56418679-49377A51-5AEC-4F68-AEED-0666C7071A10Q56938942-C1A7558F-D11B-4E06-9C5C-6118CA453B9AQ57038202-A37D5601-FC67-41C4-9281-962171286CB6Q57059314-0D74AA5A-FB8E-4B2C-A8E7-72DA3B9F55DBQ57063212-CEA08E76-AC52-443C-9A20-AFF70F381FB5Q57232155-5B081268-9800-4327-8776-00A29F7F1FB4Q57236655-74F7131D-A066-4226-BA94-CBDC4259C2EDQ57319715-55193EF9-B015-4B24-9695-F0DBB4777612Q57906429-3B40CA7F-595A-4CD6-935C-434BBD986812Q57914532-8A729E22-C7C8-47B5-9F90-AB00F8A33972
P2860
Best practices for use of stable isotope mixing models in food-web studies
description
article
@en
im Oktober 2014 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в жовтні 2014
@uk
name
Best practices for use of stable isotope mixing models in food-web studies
@en
Best practices for use of stable isotope mixing models in food-web studies
@nl
type
label
Best practices for use of stable isotope mixing models in food-web studies
@en
Best practices for use of stable isotope mixing models in food-web studies
@nl
prefLabel
Best practices for use of stable isotope mixing models in food-web studies
@en
Best practices for use of stable isotope mixing models in food-web studies
@nl
P2093
P2860
P50
P356
P1476
Best practices for use of stable isotope mixing models in food-web studies
@en
P2093
Brice X. Semmens
Donald L. Phillips
Eric J. Ward
Jonathan W. Moore
P2860
P304
P356
10.1139/CJZ-2014-0127
P577
2014-10-01T00:00:00Z