Plant community response to warming and herbivory on sub-arctic coastal terraces in Western Alaska, 2015 - 2016

To predict future changes in high latitude biomes, it is important to understand how plant communities will respond to increased temperature. Across sub-arctic systems, warming generally increases aboveground biomass in plant communities. Specifically, in arctic graminoid systems, experimental warmi...

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Bibliographic Details
Main Authors: Karen Beard, Ryan Choi
Format: Dataset
Language:unknown
Published: Arctic Data Center 2017
Subjects:
Climate change
forbs
grasses
International tundra experiment (ITEX)
plant-herbivore interactions
plant functional groups
sedges
shrubs
tundra
Yukon-Kuskokwim Delta
Calamagrostis deschampsioides
Carex aquatilis
Carex glareosa
Carex lyngbyaei
Carex ramenskii
Carex rariflora
Chrysanthemum arcticum
Conioselinum chinense
Deschampsia caespitosa
Empetrum nigrum
Festuca rubra
Leymus mollis
Ligusticum scoticum
Parnassia palustris
Poa eminens
Potentilla egedii
Primula borealis
Puccinellia phryganodes
Rumex arcticus
Salix fuscescens
Salix ovalifolia
Sedum rosea
Stellaria humifusa
Stellaria crassifolia
Triglochin palustris
Arctic
Pedersen
The ''Y''
Yukon
Kuskokwim
Subarctic
Tundra
Alaska
Online Access:https://search.dataone.org/view/urn:uuid:9cbe3926-5309-4786-8d6b-b2f56d2ab1d4
id dataone:urn:uuid:9cbe3926-5309-4786-8d6b-b2f56d2ab1d4
record_format openpolar
institution Open Polar
collection Arctic Data Center (via DataONE)
op_collection_id dataone:urn:node:ARCTIC
language unknown
topic Climate change
forbs
grasses
International tundra experiment (ITEX)
plant-herbivore interactions
plant functional groups
sedges
shrubs
tundra
Yukon-Kuskokwim Delta
Calamagrostis deschampsioides
Carex aquatilis
Carex glareosa
Carex lyngbyaei
Carex ramenskii
Carex rariflora
Chrysanthemum arcticum
Conioselinum chinense
Deschampsia caespitosa
Empetrum nigrum
Festuca rubra
Leymus mollis
Ligusticum scoticum
Parnassia palustris
Poa eminens
Potentilla egedii
Primula borealis
Puccinellia phryganodes
Rumex arcticus
Salix fuscescens
Salix ovalifolia
Sedum rosea
Stellaria humifusa
Stellaria crassifolia
Triglochin palustris
spellingShingle Climate change
forbs
grasses
International tundra experiment (ITEX)
plant-herbivore interactions
plant functional groups
sedges
shrubs
tundra
Yukon-Kuskokwim Delta
Calamagrostis deschampsioides
Carex aquatilis
Carex glareosa
Carex lyngbyaei
Carex ramenskii
Carex rariflora
Chrysanthemum arcticum
Conioselinum chinense
Deschampsia caespitosa
Empetrum nigrum
Festuca rubra
Leymus mollis
Ligusticum scoticum
Parnassia palustris
Poa eminens
Potentilla egedii
Primula borealis
Puccinellia phryganodes
Rumex arcticus
Salix fuscescens
Salix ovalifolia
Sedum rosea
Stellaria humifusa
Stellaria crassifolia
Triglochin palustris
Karen Beard
Ryan Choi
Plant community response to warming and herbivory on sub-arctic coastal terraces in Western Alaska, 2015 - 2016
topic_facet Climate change
forbs
grasses
International tundra experiment (ITEX)
plant-herbivore interactions
plant functional groups
sedges
shrubs
tundra
Yukon-Kuskokwim Delta
Calamagrostis deschampsioides
Carex aquatilis
Carex glareosa
Carex lyngbyaei
Carex ramenskii
Carex rariflora
Chrysanthemum arcticum
Conioselinum chinense
Deschampsia caespitosa
Empetrum nigrum
Festuca rubra
Leymus mollis
Ligusticum scoticum
Parnassia palustris
Poa eminens
Potentilla egedii
Primula borealis
Puccinellia phryganodes
Rumex arcticus
Salix fuscescens
Salix ovalifolia
Sedum rosea
Stellaria humifusa
Stellaria crassifolia
Triglochin palustris
description To predict future changes in high latitude biomes, it is important to understand how plant communities will respond to increased temperature. Across sub-arctic systems, warming generally increases aboveground biomass in plant communities. Specifically, in arctic graminoid systems, experimental warming has been shown to increase productivity, aboveground biomass and leaf litter production, and stimulate early-season growth. Warming can also decrease species richness, and reduce foliar nitrogen (N) in aboveground biomass over the growing season. Migrating geese are important grazers in arctic and subarctic ecosystems during summer breeding months. Avian herbivores depend on high quality forage (high N) and are often found at high enough densities to impact vegetation communities. Exclosure experiments show that goose herbivory reduces biomass of herbaceous species but increases net above-ground primary production and N concentrations of grazing-tolerant sedges, and sometimes even increases species richness. Goose herbivory also alters plant physiological processes as evidenced by increased N uptake by plants, as well as the biophysical processes that affect N cycling through trampling and fecal deposition. Thus, high-density populations of avian herbivores can have top-down control on their vegetation communities. While increasing global temperatures may increase aboveground biomass and decrease species richness in plant communities, herbivory could potentially mediate, or even reverse, these responses. For example, Post and Pedersen (2008) suggest that herbivory may exacerbate plant response to warming because both effects increase rates of productivity, while simultaneously reducing the effects of warming on aboveground biomass. If the interaction between warming and herbivory causes a shift in plant abundance and community functional groups, this could cascade through the system resulting in changes in nutrient cycling and plant-animal feedbacks. The Yukon-Kuskokwim (Y-K) Delta is one of the largest river deltas in the world and is a globally important breeding area for millions of long-distance migratory waterfowl and shorebird species. The majority of these species nest in high densities close to the ocean among lowland coastal habitat. Geese populations utilize overlapping habitats and shift from more coastal to more interior habitats over the growing season. The expectations for how vegetation responds to increasing temperature and changes in herbivory with climate change will vary for different plant communities. We propose to conduct an experiment that investigates the impact of warming and herbivory on three coastal sub-arctic vegetation communities in the Y-K Delta addressing the following questions: 1) How does warming impact vegetation biomass and community composition; 2) How does herbivory impact species composition and plant functional groups; and 3) How do the different responses to warming and herbivory interact?
format Dataset
author Karen Beard
Ryan Choi
author_facet Karen Beard
Ryan Choi
author_sort Karen Beard
title Plant community response to warming and herbivory on sub-arctic coastal terraces in Western Alaska, 2015 - 2016
title_short Plant community response to warming and herbivory on sub-arctic coastal terraces in Western Alaska, 2015 - 2016
title_full Plant community response to warming and herbivory on sub-arctic coastal terraces in Western Alaska, 2015 - 2016
title_fullStr Plant community response to warming and herbivory on sub-arctic coastal terraces in Western Alaska, 2015 - 2016
title_full_unstemmed Plant community response to warming and herbivory on sub-arctic coastal terraces in Western Alaska, 2015 - 2016
title_sort plant community response to warming and herbivory on sub-arctic coastal terraces in western alaska, 2015 - 2016
publisher Arctic Data Center
publishDate 2017
url https://search.dataone.org/view/urn:uuid:9cbe3926-5309-4786-8d6b-b2f56d2ab1d4
op_coverage Yukon–Kuskokwim Delta, Alaska
ENVELOPE(-165.6167,-165.5327,61.26,61.2497)
BEGINDATE: 2015-05-01T00:00:00Z ENDDATE: 2016-08-31T00:00:00Z
long_lat ENVELOPE(140.013,140.013,-66.668,-66.668)
ENVELOPE(-112.453,-112.453,57.591,57.591)
ENVELOPE(-165.6167,-165.5327,61.26,61.2497)
geographic Arctic
Pedersen
The ''Y''
Yukon
geographic_facet Arctic
Pedersen
The ''Y''
Yukon
genre Arctic
Carex aquatilis
Climate change
Empetrum nigrum
Kuskokwim
Puccinellia phryganodes
Stellaria humifusa
Subarctic
Tundra
Alaska
Yukon
genre_facet Arctic
Carex aquatilis
Climate change
Empetrum nigrum
Kuskokwim
Puccinellia phryganodes
Stellaria humifusa
Subarctic
Tundra
Alaska
Yukon
_version_ 1800868158130618368
spelling dataone:urn:uuid:9cbe3926-5309-4786-8d6b-b2f56d2ab1d4 2024-06-03T18:46:35+00:00 Plant community response to warming and herbivory on sub-arctic coastal terraces in Western Alaska, 2015 - 2016 Karen Beard Ryan Choi Yukon–Kuskokwim Delta, Alaska ENVELOPE(-165.6167,-165.5327,61.26,61.2497) BEGINDATE: 2015-05-01T00:00:00Z ENDDATE: 2016-08-31T00:00:00Z 2017-12-15T00:00:00Z https://search.dataone.org/view/urn:uuid:9cbe3926-5309-4786-8d6b-b2f56d2ab1d4 unknown Arctic Data Center Climate change forbs grasses International tundra experiment (ITEX) plant-herbivore interactions plant functional groups sedges shrubs tundra Yukon-Kuskokwim Delta Calamagrostis deschampsioides Carex aquatilis Carex glareosa Carex lyngbyaei Carex ramenskii Carex rariflora Chrysanthemum arcticum Conioselinum chinense Deschampsia caespitosa Empetrum nigrum Festuca rubra Leymus mollis Ligusticum scoticum Parnassia palustris Poa eminens Potentilla egedii Primula borealis Puccinellia phryganodes Rumex arcticus Salix fuscescens Salix ovalifolia Sedum rosea Stellaria humifusa Stellaria crassifolia Triglochin palustris Dataset 2017 dataone:urn:node:ARCTIC 2024-06-03T18:18:20Z To predict future changes in high latitude biomes, it is important to understand how plant communities will respond to increased temperature. Across sub-arctic systems, warming generally increases aboveground biomass in plant communities. Specifically, in arctic graminoid systems, experimental warming has been shown to increase productivity, aboveground biomass and leaf litter production, and stimulate early-season growth. Warming can also decrease species richness, and reduce foliar nitrogen (N) in aboveground biomass over the growing season. Migrating geese are important grazers in arctic and subarctic ecosystems during summer breeding months. Avian herbivores depend on high quality forage (high N) and are often found at high enough densities to impact vegetation communities. Exclosure experiments show that goose herbivory reduces biomass of herbaceous species but increases net above-ground primary production and N concentrations of grazing-tolerant sedges, and sometimes even increases species richness. Goose herbivory also alters plant physiological processes as evidenced by increased N uptake by plants, as well as the biophysical processes that affect N cycling through trampling and fecal deposition. Thus, high-density populations of avian herbivores can have top-down control on their vegetation communities. While increasing global temperatures may increase aboveground biomass and decrease species richness in plant communities, herbivory could potentially mediate, or even reverse, these responses. For example, Post and Pedersen (2008) suggest that herbivory may exacerbate plant response to warming because both effects increase rates of productivity, while simultaneously reducing the effects of warming on aboveground biomass. If the interaction between warming and herbivory causes a shift in plant abundance and community functional groups, this could cascade through the system resulting in changes in nutrient cycling and plant-animal feedbacks. The Yukon-Kuskokwim (Y-K) Delta is one of the largest river deltas in the world and is a globally important breeding area for millions of long-distance migratory waterfowl and shorebird species. The majority of these species nest in high densities close to the ocean among lowland coastal habitat. Geese populations utilize overlapping habitats and shift from more coastal to more interior habitats over the growing season. The expectations for how vegetation responds to increasing temperature and changes in herbivory with climate change will vary for different plant communities. We propose to conduct an experiment that investigates the impact of warming and herbivory on three coastal sub-arctic vegetation communities in the Y-K Delta addressing the following questions: 1) How does warming impact vegetation biomass and community composition; 2) How does herbivory impact species composition and plant functional groups; and 3) How do the different responses to warming and herbivory interact? Dataset Arctic Carex aquatilis Climate change Empetrum nigrum Kuskokwim Puccinellia phryganodes Stellaria humifusa Subarctic Tundra Alaska Yukon Arctic Data Center (via DataONE) Arctic Pedersen ENVELOPE(140.013,140.013,-66.668,-66.668) The ''Y'' ENVELOPE(-112.453,-112.453,57.591,57.591) Yukon ENVELOPE(-165.6167,-165.5327,61.26,61.2497)

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