Soil CO2 not CH4 flux determines soil carbon emission response to seasonal precipitation variation in a brackish wetland

doi:10.1093/jpe/rtaf138

J Plant Ecol ›› 2026, Vol. 19 ›› Issue (1): rtaf138.DOI: 10.1093/jpe/rtaf138

• Research Article •

Soil CO₂ not CH₄ flux determines soil carbon emission response to seasonal precipitation variation in a brackish wetland

Huiqi Zhang^1,2,3, Guangxuan Han^2,3, Wenli Jia^1,2,3, Wanxin Huang^2,3,4, Xiaoshuai Zhang^2,3, Xiaojie Wang^2,3, Mingliang Zhao^2,3, Baohua Xie^2,3, Feng Lu⁵, Jianbin Song⁵, Wei Zhang⁶ and Xiaojing Chu^2,3,*

¹School of Geography and Environment, Liaocheng University, Liaocheng 252000, China, ²CAS Key Laboratory of Coastal Environmental Processes and Ecological Remediation, Yantai Institute of Coastal Zone Research (YIC), Chinese Academy of Sciences (CAS), Shandong Key Laboratory of Coastal Environmental Processes, YICCAS, Yantai 264003, China, ³Yellow River Delta Field Observation and Research Station of Coastal Marsh Ecosystem, Chinese Academy of Sciences, Dongying 257000, China, ⁴School of Ecology, Hainan University, Haikou 570228, China, ⁵Administration Bureau of the Yellow River Delta National Nature Reserve, Dongying 257091, China, ⁶School of Environmental and Material Engineering, Yantai University, Yantai 264005, China

*Corresponding author. E-mail: xjchu@yic.ac.cn

Received:2025-03-30 Accepted:2025-08-22 Online:2025-09-19 Published:2026-02-01
Supported by:
This work was funded by National Key Research and Development Program in China (2022YFF0802101), the Natural Science Foundation of China (42101117, 42071126, U2106209), the International Science Partnership Program of the Chinese Academy of Sciences (121311KYSB20190029) and the Natural Science Foundation of Shandong Province(ZR2019BC106)

盐沼湿地土壤CO₂而非CH₄通量驱动土壤碳排放对季节性降水变化的响应

Abstract

Abstract: Global climate change-induced alterations in precipitation patterns have introduced uncertainty regarding soil carbon sequestration capacity in brackish wetlands. To investigate the effect of seasonal precipitation distribution (SPD) on soil carbon emissions, we conducted a field experiment in a brackish wetland in the Yellow River Delta, maintaining consistent annual precipitation but varying SPD (+73%, +56%, CK, −56%, and −73%). Increased precipitation during the spring was followed by decreased precipitation in the summer and fall (+73% and +56%), whereas decreased spring precipitation was followed by increased summer and fall precipitation (−56% and −73%). Precipitation remained consistent across all treatments during winter. The results revealed significant seasonal and inter-annual sensitivity of soil CO₂ fluxes to SPD, with the spring precipitation enhancement (+56%) treatment exerting a greater influence on emissions than the +73% treatment. In contrast, soil CH₄ fluxes exhibited no statistically significant variations across seasons or in response to precipitation adjustments. Furthermore, hydrological mediation of SPD established inverse water-salt dynamics: increased precipitation in spring mitigated soil salinity, promoting vegetation colonization and growth, while reduced precipitation in summer and autumn alleviated inundation pressure, enhancing vegetation productivity. Increases in soil CO₂ fluxes driven by SPD were primarily attributed to alleviation of salinity stress and vegetation-mediated carbon partitioning, whereas CH₄ fluxes remained statistically constant across precipitation regimes. Therefore, we conclude that SPD predominantly affects soil carbon emissions in the brackish wetland by modifying soil CO₂ fluxes. These findings provide mechanistic insights for refining predictive models of wetland carbon cycling under climate-driven precipitation reconstruction.

Seasonal precipitation distribution modulates soil CO₂ flux by regulating water-salt dynamics and underground root architecture, ultimately influencing soil carbon emissions from the brackish wetland.

Key words: seasonal precipitation distribution, soil CO₂ fluxes, soil salinity, fine root biomass, brackish wetland

摘要：
全球气候变化导致降水格局变化，致使盐沼湿地土壤汇不确定性上升。为探究季节性降水分配(SPD)对土壤碳排放的影响机制，本研究在黄河三角洲盐沼湿地开展了原位控制实验。基于历史降水数据(1961–2018年)，在维持年降雨量不变的前提下设置了5种SPD处理(+73%、+56%、CK、−56%和−73%)：其中，春季降水增加处理(+73%和+56%)对应夏秋季降水等比例减少，而春季降水减少处理(−56%和−73%)则伴随夏秋季降水等比例增加，所有处理冬季降水量保持一致。结果表明，SPD变化显著改变土壤CO₂通量年际动态，并且+56%处理对土壤CO₂排放的促进作用高于+73%处理。相比之下，SPD对土壤CH₄通量无显著影响。结构方程模型显示，SPD驱动的CO₂通量增加主要源于春季盐分胁迫解除和植被碳分配过程的协同作用。这主要与SPD通过调控水盐动态产生的双重效应有关：春季增雨缓解土壤盐渍化胁迫，显著促进植被定植；而夏秋季减雨则通过降低淹水压力提升植被生产力。上述结果为优化湿地碳循环模型中的降水参数提供了理论依据。

关键词: 季节性降水分配, 土壤二氧化碳通量, 土壤盐分, 细根生物量, 盐沼湿地

Huiqi Zhang, Guangxuan Han, Wenli Jia, Wanxin Huang, Xiaoshuai Zhang, Xiaojie Wang, Mingliang Zhao, Baohua Xie, Feng Lu, Jianbin Song, Wei Zhang, Xiaojing Chu. Soil CO₂ not CH₄ flux determines soil carbon emission response to seasonal precipitation variation in a brackish wetland[J]. J Plant Ecol, 2026, 19(1): 1-.

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Soil CO₂ not CH₄ flux determines soil carbon emission response to seasonal precipitation variation in a brackish wetland

盐沼湿地土壤CO₂而非CH₄通量驱动土壤碳排放对季节性降水变化的响应

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