Effects of warming and nitrogen fertilization on GHG flux in an alpine swamp meadow of a permafrost region

Uncertainties in the seasonal changes of greenhouse gases (GHG) fluxes in wetlands limit our accurate understanding of the responses of permafrost ecosystems to future warming and increased nitrogen (N) deposition. Therefore, in an alpine swamp meadow in the hinterland of the Qinghai-Tibet Plateau,...

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Bibliographic Details
Published in:The Science of the total environment 2017-12, Vol.601-602, p.1389-1399
Main Authors: Chen, Xiaopeng, Wang, Genxu, Zhang, Tao, Mao, Tianxu, Wei, Da, Song, Chunlin, Hu, Zhaoyong, Huang, Kewei
Format: Article
Language:English
Subjects:
Greenhouse gas
Nitrogen addition
Seasonal variation
Simulated warming
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Summary:Uncertainties in the seasonal changes of greenhouse gases (GHG) fluxes in wetlands limit our accurate understanding of the responses of permafrost ecosystems to future warming and increased nitrogen (N) deposition. Therefore, in an alpine swamp meadow in the hinterland of the Qinghai-Tibet Plateau, a simulated warming with N fertilization experiment was conducted to investigate the key GHG fluxes (ecosystem respiration [Re], CH4 and N2O) in the early (EG), mid (MG) and late (LG) growing seasons. Results showed that warming (6.2 °C) increased the average seasonal Re by 30.9% and transformed the alpine swamp meadow from a N2O sink to a source, whereas CH4 flux was not significantly affected. N fertilization (4 g N m−2 a−1) alone had no significant effect on the fluxes of GHGs. The interaction of warming and N fertilization increased CH4 uptake by 69.6% and N2O emissions by 26.2% compared with warming, whereas the Re was not significantly affected. During the EG, although the soil temperature sensitivity of the Re was the highest, the effect of warming on the Re was the weakest. The primary driving factor for Re was soil surface temperature, whereas soil moisture controlled CH4 flux, and the N2O flux was primarily affected by rain events. The results indicated: (i) increasing N deposition has both positive and negative feedbacks on GHG fluxes in response to climate warming; (ii) during soil thawing process at active layer, low temperature of deep frozen soils have a negative contribution to Re in alpine ecosystems; and (iii) although these alpine wetland ecosystems are buffers against increased temperature, their feedbacks on climate change cannot be ignored because of the large soil organic carbon pool and high temperature sensitivity of the Re. [Display omitted] •GHG fluxes were measured using the static chamber and gas chromatograph method.•Under the scenario of warming, increasing N deposition will increase CH4 uptake and N2O emission.•Low temperature of deep frozen soils has a negative contribution to ecosystem respiration.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2017.06.028