Temporal variations of carbon and water fluxes in a subtropical mangrove forest: Insights from a decade-long eddy covariance measurement

Gou, Ruikun; Buchmann, Nina; Chi, Jinshu; Luo, Yunpeng; Mo, Lidong; Shekhar, Ankit; Feigenwinter, Iris; Hortnagl, Lukas; Lu, Weizhi; Cui, Xiaowei; Meng, Yuchen; Song, Shanshan; Lin, Guangxuan; Chen, Yuechao; Liang, Jie; Guo, Jiemin; Peng, Haijun; Lin, Guanghui

doi:10.1016/j.agrformet.2023.109764

Research article2023Peer reviewed

Temporal variations of carbon and water fluxes in a subtropical mangrove forest: Insights from a decade-long eddy covariance measurement

Gou, Ruikun; Buchmann, Nina; Chi, Jinshu; Luo, Yunpeng; Mo, Lidong; Shekhar, Ankit; Feigenwinter, Iris; Hortnagl, Lukas; Lu, Weizhi; Cui, Xiaowei; Meng, Yuchen; Song, Shanshan; Lin, Guangxuan; Chen, Yuechao; Liang, Jie; Guo, Jiemin; Peng, Haijun; Lin, Guanghui

Abstract

Mangroves, highly efficient ecosystems in sequestering CO2, are strongly impacted by climate change. The lack of long-term observation in mangroves hinders the evaluation of seasonal and inter-annual variability in carbon and water fluxes and their responses to various environmental drivers. In this study, we measured net ecosystem CO2 exchange and evapotranspiration between the atmosphere and subtropical mangroves using the eddy covariance technique over a decade (2010-2019) in southern China. This mangrove forest acted as a strong CO2 sink, with annual net ecosystem production (NEP) ranging from 622.5 to 832.8 g C m(-2) year(-1). The annual evapotranspiration (ET) varied between 934.6 and 1004.9 mm year(-1). During the study period, ET consistently remained higher in the wet season (May to October) compared to the dry season, while NEP did not exhibit consistent seasonal variation. Path analysis indicated that during the dry season, NEP was primarily influenced by global solar radiation and vapor pressure deficit. However, in the wet season, NEP was regulated by a combination of global solar radiation, vapor pressure deficit, air temperature, and tidal inundation time. Additionally, the promoting effect of global solar radiation on NEP decreased in the wet season, while the inhibitory influences of higher temperature and vapor pressure deficit on NEP intensified during the period. Unlike NEP, the dominant factors affecting ET (global solar radiation, air temperature, and vapor pressure deficit) and their intensities remained relatively consistent during both seasons. Furthermore, the relative importance of global solar radiation on NEP and ET increased over the decade, while the influence of tidal inundation time diminished. This study not only improves the understanding of the response of subtropical mangroves to climate change but also provides a valuable benchmark dataset to validate the interannual variability of mangrove carbon and water fluxes estimated from the models.

Keywords

Coastal wetland; Blue carbon; Net ecosystem production; CO2 budget; Evapotranspiration

Published in

Agricultural and Forest Meteorology
2023, Volume: 343, article number: 109764
Publisher: ELSEVIER

SLU Authors

Peng, Haijun
- Department of Forest Ecology and Management, Swedish University of Agricultural Sciences

Sustainable Development Goals

SDG13 Take urgent action to combat climate change and its impacts

UKÄ Subject classification

Meteorology and Atmospheric Sciences
Forest Science

Publication identifier

DOI: https://doi.org/10.1016/j.agrformet.2023.109764

Permanent link to this page (URI)

https://res.slu.se/id/publ/126970