Effects of warming and rainfall pulses on soil respiration in a biological soil crust-dominated desert ecosystem

[Display omitted] •Soil respiration in BSC-dominated areas was suppressed under warmer conditions.•The inhibited soil respiration by warming was greater on the moss than lichen crust.•Soil respiration in BSC-dominated areas was significantly induced by rainfall pulses.•Diel hysteresis between soil r...

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Bibliographic Details
Published in:Geoderma 2021-01, Vol.381, p.114683, Article 114683
Main Authors: Guan, Chao, Zhang, Peng, Zhao, Changming, Li, Xinrong
Format: Article
Language:English
Subjects:
Biological soil crust
Diel hysteresis
Precipitation
Soil respiration
Warming
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Summary:[Display omitted] •Soil respiration in BSC-dominated areas was suppressed under warmer conditions.•The inhibited soil respiration by warming was greater on the moss than lichen crust.•Soil respiration in BSC-dominated areas was significantly induced by rainfall pulses.•Diel hysteresis between soil respiration and temperature was modified by rainfall. Biological soil crusts (BSCs) across desert ecosystems play an important role in modulating terrestrial carbon cycles. Global warming and changes in precipitation patterns are expected to be important triggers for biological activity in BSC-dominated desert ecosystems. Therefore, it is crucial to study the effects of warming and rainfall pulses on soil respiration dynamics at BSC-dominated microsites to predict terrestrial carbon cycling under climate change. In this study, soil respiration rates were monitored continuously during three types of natural precipitation events in lichen-dominated and moss-dominated crusts in both control and warming treatments. Our results revealed that soil respiration was inhibited in BSC-dominated microsites in the warming treatment because of reduced soil water content induced by the warmer conditions, and that the extent of inhibition was lower in the lichen-dominated crusts than in the moss-dominated crusts. During all the precipitation events, soil respiration rates were significantly increased by rainfall pulses and gradually declined thereafter. Over the daily cycle, the clockwise diel hysteresis loop between soil respiration and soil temperature was modified by soil water availability, which was affected by the magnitude of rainfall pulses. Moreover, the effect of photosynthetically active radiation and the mismatch between the depth of carbon dioxide (CO2) production and soil temperature measurement may have contributed to the diel hysteresis pattern. Our results indicated that warming and different types of precipitation events in BSC-dominated desert ecosystems impact soil carbon release through changes in the magnitude of soil respiration.
ISSN:0016-7061
1872-6259
DOI:10.1016/j.geoderma.2020.114683