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Coastal reservoirs as a source of nitrous oxide: Spatio-temporal patterns and assessment strategy

Yang, Ping; Lu, Miaohui; Tang, Kam W; Yang, Hong; Lai, Derrick YF; Tong, Chuan; Chun, Kwok Pan; Zhang, Linhai; Tang, Chen

Coastal reservoirs as a source of nitrous oxide: Spatio-temporal patterns and assessment strategy Thumbnail


Authors

Ping Yang

Miaohui Lu

Kam W Tang

Hong Yang

Derrick YF Lai

Chuan Tong

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Dr Kwok Chun Kwok.Chun@uwe.ac.uk
Lecturer in Environmental Managment

Linhai Zhang

Chen Tang



Abstract

Coastal reservoirs are widely regarded as a viable solution to the water scarcity problem faced by coastal cities with growing populations. As a result of the accumulation of anthropogenic wastes and the alteration of hydroecological processes, these reservoirs may also become the emission hotspots of nitrous oxide (N2O). Hitherto, accurate global assessment of N2O emission suffers from the scarcity and low spatio-temporal resolution of field data, especially from small coastal reservoirs with high spatial heterogeneity and multiple water sources. In this study, we measured the surface water N2O concentrations and emissions at a high spatial resolution across three seasons in a subtropical coastal reservoir in southeastern China, which was hydrochemically highly heterogeneous because of the combined influence of river runoff, aquacultural discharge, industrial discharge and municipal sewage. Both N2O concentration and emission exhibited strong spatio-temporal variations, which were correlated with nitrogen loading from the river and wastewater discharge. The mean N2O concentration and emission were found to be significantly higher in the summer than in spring and autumn. The results of redundancy analysis showed that NH4+-N explained the greatest variance in N2O emission, which implied that nitrification was the main microbial pathway for N2O production in spite of the potentially increasing importance of denitrification of NO3−-N in the summer. The mean N2O emission across the whole reservoir was 107 μg m−2 h−1, which was more than an order of magnitude higher than that from global lakes and reservoirs. Based on our results of Monte Carlo simulations, a minimum of 15 sampling points per km2 would be needed to produce representative and reliable N2O estimates in such a spatially heterogeneous aquatic system. Overall, coastal reservoirs could play an increasingly important role in future climate change via their N2O emission to the atmosphere as water demand and anthropogenic pressure continue to rise.

Journal Article Type Article
Acceptance Date May 14, 2021
Online Publication Date May 21, 2021
Publication Date Oct 10, 2021
Deposit Date Jan 18, 2022
Publicly Available Date May 22, 2022
Journal Science of the Total Environment
Print ISSN 0048-9697
Electronic ISSN 1879-1026
Publisher Elsevier
Peer Reviewed Peer Reviewed
Volume 790
Article Number 147878
DOI https://doi.org/10.1016/j.scitotenv.2021.147878
Public URL https://uwe-repository.worktribe.com/output/8545673

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