Non-growing-season soil respiration is controlled by freezing and thawing processes in the summer monsoon-dominated Tibetan alpine grassland

The Tibetan alpine grasslands, sharing many features with arctic tundra ecosystems, have a unique non-growing-season climate that is usually dry and without persistent snow cover. Pronounced winter warming recently observed in this ecosystem may significantly alter the non-growing-season carbon cycl...

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Bibliographic Details
Main Authors: Wang, Yonghui, Liu, Huiying, Chung, Haegeun, Yu, Lingfei, Mi, Zhaorong, Geng, Yan, Jing, Xin, Wang, Shiping, Zeng, Hui, Cao, Guangmin, Zhao, Xinquan, He, Jin-Sheng
Format: Article in Journal/Newspaper
Language:English
Published: 2014
Subjects:
Winter Soil Respiration
Carbon Cycling
Alpine Ecosystem
Soil Freezing
Tibetan Plateau
Science & Technology
Life Sciences & Biomedicine
Physical Sciences
INCREASED SNOW DEPTH
CO2 EFFLUX
TEMPERATURE SENSITIVITY
CLIMATE-CHANGE
ARCTIC TUNDRA
MICROBIAL RESPIRATION
ECOSYSTEM RESPIRATION
SOLAR-RADIATION
VEGETATION TYPE
NORTH-AMERICA
Environmental Sciences & Ecology
Geology
Meteorology & Atmospheric Sciences
Environmental Sciences
Geosciences
Multidisciplinary
Arctic
Climate change
Tundra
Online Access:http://210.75.249.4/handle/363003/4180
Description
Summary:The Tibetan alpine grasslands, sharing many features with arctic tundra ecosystems, have a unique non-growing-season climate that is usually dry and without persistent snow cover. Pronounced winter warming recently observed in this ecosystem may significantly alter the non-growing-season carbon cycle processes such as soil respiration (R-s), but detailed measurements to assess the patterns, drivers of, and potential feedbacks on R-s have not been made yet. We conducted a 4 year study on R-s using a unique R-s measuring system, composed of an automated soil CO2 flux sampling system and a custom-made container, to facilitate measurements in this extreme environment. We found that in the nongrowing season, (1) cumulative R-s was 82-89g C m(-2), accounting for 11.8-13.2% of the annual total R-s; (2) surface soil freezing controlled the diurnal pattern of R-s and bulk soil freezing induced lower reference respiration rate (R-0) and temperature sensitivity (Q(10)) than those in the growing season (0.40-0.53 versus 0.84-1.32 mu mol CO2 m(-2)s(-1) for R-0 and 2.5-2.9 versus 2.9-5.6 for Q(10)); and (3) the intraannual variation in cumulative R-s was controlled by accumulated surface soil temperature. We found that in the summer monsoon-dominated Tibetan alpine grassland, surface soil freezing, bulk soil freezing, and accumulated surface soil temperature are the day-, season-, and year-scale drivers of the non-growing-season R-s, respectively. Our results suggest that warmer winters can trigger carbon loss from this ecosystem because of higher Q(10) of thawed than frozen soils. The Tibetan alpine grasslands, sharing many features with arctic tundra ecosystems, have a unique non-growing-season climate that is usually dry and without persistent snow cover. Pronounced winter warming recently observed in this ecosystem may significantly alter the non-growing-season carbon cycle processes such as soil respiration (R-s), but detailed measurements to assess the patterns, drivers of, and potential feedbacks on R-s have not been ...

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