Data_Sheet_1_The Importance of Incorporating Landscape Change for Predictions of Climate-Induced Plant Phenological Shifts.pdf

Warming in the high Arctic is occurring at the fastest rate on the planet, raising concerns over how this global change driver will influence plant community composition, the timing of vegetation phenological events, and the wildlife that rely on them. In this region, as much as 50% of near-surface...

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Main Authors:	Chelsea Chisholm (3275457), Michael S. Becker (3247881), Wayne H. Pollard (3247878)
Format:	Dataset
Language:	unknown
Published:	2020
Subjects:	Botany Plant Biology Plant Systematics and Taxonomy Plant Cell and Molecular Biology Plant Developmental and Reproductive Biology Plant Pathology Plant Physiology Plant Biology not elsewhere classified leaf phenology flower phenology permafrost geomorphology ground stability Arctic plant ecology Ellesmere Island Canada Ice Thermokarst
Online Access:	https://doi.org/10.3389/fpls.2020.00759.s001

id	ftpurdueuniv:oai:figshare.com:article/12561272
record_format	openpolar
spelling	ftpurdueuniv:oai:figshare.com:article/12561272 2023-05-15T14:54:12+02:00 Data_Sheet_1_The Importance of Incorporating Landscape Change for Predictions of Climate-Induced Plant Phenological Shifts.pdf Chelsea Chisholm (3275457) Michael S. Becker (3247881) Wayne H. Pollard (3247878) 2020-06-25T04:09:15Z https://doi.org/10.3389/fpls.2020.00759.s001 unknown https://figshare.com/articles/Data_Sheet_1_The_Importance_of_Incorporating_Landscape_Change_for_Predictions_of_Climate-Induced_Plant_Phenological_Shifts_pdf/12561272 doi:10.3389/fpls.2020.00759.s001 CC BY 4.0 CC-BY Botany Plant Biology Plant Systematics and Taxonomy Plant Cell and Molecular Biology Plant Developmental and Reproductive Biology Plant Pathology Plant Physiology Plant Biology not elsewhere classified leaf phenology flower phenology permafrost geomorphology ground stability Arctic plant ecology Dataset 2020 ftpurdueuniv https://doi.org/10.3389/fpls.2020.00759.s001 2020-06-25T10:06:47Z Warming in the high Arctic is occurring at the fastest rate on the planet, raising concerns over how this global change driver will influence plant community composition, the timing of vegetation phenological events, and the wildlife that rely on them. In this region, as much as 50% of near-surface permafrost is composed of thermally sensitive ground ice that when melted produces substantial changes in topography and microbiome conditions. We take advantage of natural variations in permafrost melt to conduct a space-for-time study on Ellesmere Island in northern Canada. We demonstrate that phenological timing can be delayed in thermokarst areas when compared to stable ground, and that this change is a function of shifting species composition in these vegetation communities as well as delayed timing within species. These findings suggest that a warming climate could result in an overall broadening of blooming and leafing windows at the landscape level when these delayed timings are taken into consideration with the projected advance of phenological timings in ice-poor areas. We emphasize that the impacts of geomorphic processes on key phenological drivers are essential for enhancing our understanding of community response to climate warming in the high Arctic, with implications for ecosystem functioning and trophic interactions. Dataset Arctic Ellesmere Island Ice permafrost Thermokarst Purdue University: e-Pubs Arctic Ellesmere Island Canada
institution	Open Polar
collection	Purdue University: e-Pubs
op_collection_id	ftpurdueuniv
language	unknown
topic	Botany Plant Biology Plant Systematics and Taxonomy Plant Cell and Molecular Biology Plant Developmental and Reproductive Biology Plant Pathology Plant Physiology Plant Biology not elsewhere classified leaf phenology flower phenology permafrost geomorphology ground stability Arctic plant ecology
spellingShingle	Botany Plant Biology Plant Systematics and Taxonomy Plant Cell and Molecular Biology Plant Developmental and Reproductive Biology Plant Pathology Plant Physiology Plant Biology not elsewhere classified leaf phenology flower phenology permafrost geomorphology ground stability Arctic plant ecology Chelsea Chisholm (3275457) Michael S. Becker (3247881) Wayne H. Pollard (3247878) Data_Sheet_1_The Importance of Incorporating Landscape Change for Predictions of Climate-Induced Plant Phenological Shifts.pdf
topic_facet	Botany Plant Biology Plant Systematics and Taxonomy Plant Cell and Molecular Biology Plant Developmental and Reproductive Biology Plant Pathology Plant Physiology Plant Biology not elsewhere classified leaf phenology flower phenology permafrost geomorphology ground stability Arctic plant ecology
description	Warming in the high Arctic is occurring at the fastest rate on the planet, raising concerns over how this global change driver will influence plant community composition, the timing of vegetation phenological events, and the wildlife that rely on them. In this region, as much as 50% of near-surface permafrost is composed of thermally sensitive ground ice that when melted produces substantial changes in topography and microbiome conditions. We take advantage of natural variations in permafrost melt to conduct a space-for-time study on Ellesmere Island in northern Canada. We demonstrate that phenological timing can be delayed in thermokarst areas when compared to stable ground, and that this change is a function of shifting species composition in these vegetation communities as well as delayed timing within species. These findings suggest that a warming climate could result in an overall broadening of blooming and leafing windows at the landscape level when these delayed timings are taken into consideration with the projected advance of phenological timings in ice-poor areas. We emphasize that the impacts of geomorphic processes on key phenological drivers are essential for enhancing our understanding of community response to climate warming in the high Arctic, with implications for ecosystem functioning and trophic interactions.
format	Dataset
author	Chelsea Chisholm (3275457) Michael S. Becker (3247881) Wayne H. Pollard (3247878)
author_facet	Chelsea Chisholm (3275457) Michael S. Becker (3247881) Wayne H. Pollard (3247878)
author_sort	Chelsea Chisholm (3275457)
title	Data_Sheet_1_The Importance of Incorporating Landscape Change for Predictions of Climate-Induced Plant Phenological Shifts.pdf
title_short	Data_Sheet_1_The Importance of Incorporating Landscape Change for Predictions of Climate-Induced Plant Phenological Shifts.pdf
title_full	Data_Sheet_1_The Importance of Incorporating Landscape Change for Predictions of Climate-Induced Plant Phenological Shifts.pdf
title_fullStr	Data_Sheet_1_The Importance of Incorporating Landscape Change for Predictions of Climate-Induced Plant Phenological Shifts.pdf
title_full_unstemmed	Data_Sheet_1_The Importance of Incorporating Landscape Change for Predictions of Climate-Induced Plant Phenological Shifts.pdf
title_sort	data_sheet_1_the importance of incorporating landscape change for predictions of climate-induced plant phenological shifts.pdf
publishDate	2020
url	https://doi.org/10.3389/fpls.2020.00759.s001
geographic	Arctic Ellesmere Island Canada
geographic_facet	Arctic Ellesmere Island Canada
genre	Arctic Ellesmere Island Ice permafrost Thermokarst
genre_facet	Arctic Ellesmere Island Ice permafrost Thermokarst
op_relation	https://figshare.com/articles/Data_Sheet_1_The_Importance_of_Incorporating_Landscape_Change_for_Predictions_of_Climate-Induced_Plant_Phenological_Shifts_pdf/12561272 doi:10.3389/fpls.2020.00759.s001
op_rights	CC BY 4.0
op_rightsnorm	CC-BY
op_doi	https://doi.org/10.3389/fpls.2020.00759.s001
_version_	1766325921032175616

Data_Sheet_1_The Importance of Incorporating Landscape Change for Predictions of Climate-Induced Plant Phenological Shifts.pdf

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