Seasonal Evolution of Soil Respiration and Sources of Respirable Carbon in Three Forest Stands on the Loess Plateau of China

• Published in: Land degradation & development Vol. 35; no. 18; pp. 5701 - 5712
• Main Authors: Guan, Xueyu, Zhang, Yan, Niu, Hongbo, Shi, Peng, Cao, Manhong, Zu, Pengju, Xu, Duoxun, Zhao, Qianzhuo, Wang, Bo, Cui, Lingzhou, Gómez, José A.
• Format: Journal Article
• Language: English
• Published: Chichester, UK John Wiley & Sons, Ltd 01.12.2024; Wiley Subscription Services, Inc
• Subjects: 13C; autumn; Carbon; Carbon 13; Carbon dioxide; carbon sinks; Carbon sources; China; CO2; Environmental factors; Forests; land degradation; Litter; Microorganisms; Mixed forests; Organic matter; Pinus tabuliformis; Quercus acutissima; Respiration; Seasonal variations; Soil analysis; Soil investigations; Soil microorganisms; Soil moisture; Soil organic matter; soil respiration; Soil surfaces; Soil temperature; Soils; stand structure; Surface temperature; Winter; Loess Plateau; China
• ISSN: 1085-3278; 1099-145X; 1099-145X
• DOI: 10.1002/ldr.5325

ABSTRACT The litter and root systems of forest stands can influence soil organic matter content and are subject to the effects of soil temperature and moisture. Through the decomposition activity of soil microorganisms, a portion of the carbon stored in aboveground vegetation is transferred to the underground carbon pool, thereby impacting soil respiration. When we investigated the effects of various components and environmental factors on soil respiration, 13C served as an effective tool for analyzing their contributions. In this study, conducted in a region of the Loess Plateau, three forest stands' soil respiration (Quercus acutissima forest—QAF, Pinus tabuliformis forest—PTF, and mixed forests—MF) was examined. Both soil respiration rate (Rs) and 13C exhibited seasonal fluctuations linked to changes in surface soil temperature and moisture. The soil respiration rate of all forest stands decreased to below 1 μmol m−2 s−1 during winter. The average range of δ13C fell between −22‰ and −17‰. Over the course of four seasons, we monitored soil respiration and identified hydrothermal factors. The correlation between hydrothermal factors and CO2 releases from soil respiration varied significantly across seasons among different forest structures (p < 0.001). Additionally, the contribution of litter to soil respiration was the main source and it was higher in autumn and winter, with a maximum of over 75%. This study holds significant importance for understanding the processes underlying the carbon sources of soil respiration.