Divergence in ecosystem carbon fluxes and soil nitrogen characteristics across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone

Alpine ecosystem carbon cycling is sensitive to climate change, particularly in the transition zones between biomes. Soil nitrogen conditions, including the ammonium to nitrate (NH4+/NO3-) ratio, regulate ecosystem carbon uptake by coupling carbon-nitrogen cycle. The largest alpine pasture on Earth...

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Published in:Science of The Total Environment
Main Authors: Liu, Yongwen, Geng, Xiaodong, Tenzintarchen, Wei, Da, Dai, Dongxue, Xu-Ri
Format: Report
Language:English
Published: ELSEVIER 2020
Subjects:
Climate change
Carbon and nitrogen cycling
Net ecosystem carbon dioxide exchange
Gross ecosystem photosynthesis
Denitrification rate
Tibetan Plateau
BIOLOGICAL NITRIFICATION INHIBITION
CLIMATE-CHANGE
OXIDE EMISSIONS
VEGETATION CHARACTERISTICS
TEMPERATURE SENSITIVITY
INORGANIC NITROGEN
CO2 EXCHANGE
ICE CORE
MOISTURE
Environmental Sciences & Ecology
Environmental Sciences
ice core
Online Access:http://ir.imde.ac.cn/handle/131551/50663
https://doi.org/10.1016/j.scitotenv.2020.142453
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record_format openpolar
spelling ftchinacadscimhe:oai:ir.imde.ac.cn:131551/50663 2023-05-15T16:39:27+02:00 Divergence in ecosystem carbon fluxes and soil nitrogen characteristics across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone Liu, Yongwen Geng, Xiaodong Tenzintarchen Wei, Da Dai, Dongxue Xu-Ri 2020-12-15 http://ir.imde.ac.cn/handle/131551/50663 https://doi.org/10.1016/j.scitotenv.2020.142453 英语 eng ELSEVIER SCIENCE OF THE TOTAL ENVIRONMENT http://ir.imde.ac.cn/handle/131551/50663 doi:10.1016/j.scitotenv.2020.142453 Climate change Carbon and nitrogen cycling Net ecosystem carbon dioxide exchange Gross ecosystem photosynthesis Denitrification rate Tibetan Plateau BIOLOGICAL NITRIFICATION INHIBITION CLIMATE-CHANGE OXIDE EMISSIONS VEGETATION CHARACTERISTICS TEMPERATURE SENSITIVITY INORGANIC NITROGEN CO2 EXCHANGE ICE CORE MOISTURE Environmental Sciences & Ecology Environmental Sciences 期刊论文 2020 ftchinacadscimhe https://doi.org/10.1016/j.scitotenv.2020.142453 2022-12-19T18:27:45Z Alpine ecosystem carbon cycling is sensitive to climate change, particularly in the transition zones between biomes. Soil nitrogen conditions, including the ammonium to nitrate (NH4+/NO3-) ratio, regulate ecosystem carbon uptake by coupling carbon-nitrogen cycle. The largest alpine pasture on Earth is distributed on the Tibetan Plateau, where alpine biome transition zones are also widely distributed. However, it is largely unknown how the soil NH4+/NO3- ratio and net ecosystem CO2 exchange vary among vegetation types in the alpine biome transition zones due to a lack of in situ field observations. Here, we investigated soil NH4+/NO3- ratio and ecosystem carbon fluxes across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone on the central Tibetan Plateau. The results showed that soil NH4+/NO3- ratio was lowest in the alpine steppe (driest environment), which had the highest soil pH, and highest in the alpine swamp (wettest environment), which had the lowest soil pH. We proposed a theoretical framework describing how soil moisture regulates soil NH4+/NO3- ratio by altering both the denitrification process and soil pH. We further found that the growing season average net ecosystem CO2 exchange for the alpine steppe, alpine meadow and alpine swamp was -1.46, - 1.90 and -5.43 mu mol m(-2) s(-1), respectively. This divergence in net ecosystem CO2 exchange across the three grasslands is primarily explained by divergence in gross ecosystem photosynthesis, rather than ecosystem respiration. The air temperature sensitivity of ecosystem respiration (Q(10)) for the alpine steppe, alpine meadow and alpine swamp was 1.73 +/- 0.05, 1.44 +/- 0.03 and 2.43 +/- 0.45, respectively. Our study highlights large differences in both soil nutrient and ecosystem carbon uptake across different vegetation types in an alpine biome transition zone. More in situ investigations in various biome transition zones are urgently needed to quantitatively understand the spatial pattern of alpine ecosystem ... Report ice core IMHE OpenIR (Institute of Mountain Hazards and Environment, Chinese Academy of Sciences) Science of The Total Environment 748 142453
institution Open Polar
collection IMHE OpenIR (Institute of Mountain Hazards and Environment, Chinese Academy of Sciences)
op_collection_id ftchinacadscimhe
language English
topic Climate change
Carbon and nitrogen cycling
Net ecosystem carbon dioxide exchange
Gross ecosystem photosynthesis
Denitrification rate
Tibetan Plateau
BIOLOGICAL NITRIFICATION INHIBITION
CLIMATE-CHANGE
OXIDE EMISSIONS
VEGETATION CHARACTERISTICS
TEMPERATURE SENSITIVITY
INORGANIC NITROGEN
CO2 EXCHANGE
ICE CORE
MOISTURE
Environmental Sciences & Ecology
Environmental Sciences
spellingShingle Climate change
Carbon and nitrogen cycling
Net ecosystem carbon dioxide exchange
Gross ecosystem photosynthesis
Denitrification rate
Tibetan Plateau
BIOLOGICAL NITRIFICATION INHIBITION
CLIMATE-CHANGE
OXIDE EMISSIONS
VEGETATION CHARACTERISTICS
TEMPERATURE SENSITIVITY
INORGANIC NITROGEN
CO2 EXCHANGE
ICE CORE
MOISTURE
Environmental Sciences & Ecology
Environmental Sciences
Liu, Yongwen
Geng, Xiaodong
Tenzintarchen
Wei, Da
Dai, Dongxue
Xu-Ri
Divergence in ecosystem carbon fluxes and soil nitrogen characteristics across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone
topic_facet Climate change
Carbon and nitrogen cycling
Net ecosystem carbon dioxide exchange
Gross ecosystem photosynthesis
Denitrification rate
Tibetan Plateau
BIOLOGICAL NITRIFICATION INHIBITION
CLIMATE-CHANGE
OXIDE EMISSIONS
VEGETATION CHARACTERISTICS
TEMPERATURE SENSITIVITY
INORGANIC NITROGEN
CO2 EXCHANGE
ICE CORE
MOISTURE
Environmental Sciences & Ecology
Environmental Sciences
description Alpine ecosystem carbon cycling is sensitive to climate change, particularly in the transition zones between biomes. Soil nitrogen conditions, including the ammonium to nitrate (NH4+/NO3-) ratio, regulate ecosystem carbon uptake by coupling carbon-nitrogen cycle. The largest alpine pasture on Earth is distributed on the Tibetan Plateau, where alpine biome transition zones are also widely distributed. However, it is largely unknown how the soil NH4+/NO3- ratio and net ecosystem CO2 exchange vary among vegetation types in the alpine biome transition zones due to a lack of in situ field observations. Here, we investigated soil NH4+/NO3- ratio and ecosystem carbon fluxes across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone on the central Tibetan Plateau. The results showed that soil NH4+/NO3- ratio was lowest in the alpine steppe (driest environment), which had the highest soil pH, and highest in the alpine swamp (wettest environment), which had the lowest soil pH. We proposed a theoretical framework describing how soil moisture regulates soil NH4+/NO3- ratio by altering both the denitrification process and soil pH. We further found that the growing season average net ecosystem CO2 exchange for the alpine steppe, alpine meadow and alpine swamp was -1.46, - 1.90 and -5.43 mu mol m(-2) s(-1), respectively. This divergence in net ecosystem CO2 exchange across the three grasslands is primarily explained by divergence in gross ecosystem photosynthesis, rather than ecosystem respiration. The air temperature sensitivity of ecosystem respiration (Q(10)) for the alpine steppe, alpine meadow and alpine swamp was 1.73 +/- 0.05, 1.44 +/- 0.03 and 2.43 +/- 0.45, respectively. Our study highlights large differences in both soil nutrient and ecosystem carbon uptake across different vegetation types in an alpine biome transition zone. More in situ investigations in various biome transition zones are urgently needed to quantitatively understand the spatial pattern of alpine ecosystem ...
format Report
author Liu, Yongwen
Geng, Xiaodong
Tenzintarchen
Wei, Da
Dai, Dongxue
Xu-Ri
author_facet Liu, Yongwen
Geng, Xiaodong
Tenzintarchen
Wei, Da
Dai, Dongxue
Xu-Ri
author_sort Liu, Yongwen
title Divergence in ecosystem carbon fluxes and soil nitrogen characteristics across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone
title_short Divergence in ecosystem carbon fluxes and soil nitrogen characteristics across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone
title_full Divergence in ecosystem carbon fluxes and soil nitrogen characteristics across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone
title_fullStr Divergence in ecosystem carbon fluxes and soil nitrogen characteristics across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone
title_full_unstemmed Divergence in ecosystem carbon fluxes and soil nitrogen characteristics across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone
title_sort divergence in ecosystem carbon fluxes and soil nitrogen characteristics across alpine steppe, alpine meadow and alpine swamp ecosystems in a biome transition zone
publisher ELSEVIER
publishDate 2020
url http://ir.imde.ac.cn/handle/131551/50663
https://doi.org/10.1016/j.scitotenv.2020.142453
genre ice core
genre_facet ice core
op_relation SCIENCE OF THE TOTAL ENVIRONMENT
http://ir.imde.ac.cn/handle/131551/50663
doi:10.1016/j.scitotenv.2020.142453
op_doi https://doi.org/10.1016/j.scitotenv.2020.142453
container_title Science of The Total Environment
container_volume 748
container_start_page 142453
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