Depth and Seasonality of Soil Respiration in Caragana korshinskii Plantation on the Loess Plateau.
Yarong Sun, Yunming Chen
Abstract
Open AccessQuantifying deep soil (10-100 cm) and non-growing-season soil respiration (SR) is crucial for refining carbon (C) cycle models, yet the regulatory mechanisms governing these processes remain unclear. The novelty of this study lies in its focus on deep soils and non-growing seasons to elucidate how soil properties regulate SR under these special conditions. We conducted an on-site field experiment in the Caragana korshinskii plantation, measuring SR at soil depths of 0-10 cm, 10-50 cm, and 50-100 cm during the non-growing season and growing. The results suggested that the annual cumulative soil CO2 fluxes reached 510.1 (0-10 cm), 131.5 (10-50 cm), and 45.3 g CO2·m-2 (50-100 cm). These emissions during the non-growing season accounted for 33%, 31%, and 32%, respectively. The soil physical properties (temperature, moisture, bulk density) explained the greatest variation in SR during growing and non-growing periods, followed by the biological properties (α-diversity, root biomass) and chemical properties (soil organic C, ammonium nitrogen, total C/nitrogen ratio). Depth-specific analysis demonstrated that soil physical properties explained the most SR variance at three depths with independent contributions of 78.9% (0-10 cm), 89.7% (10-50 cm), and 76.9% (50-100 cm). These values exceeded the independent contributions of chemical properties (70.3%, 70.9%, 60.0%) and biological properties (54.9%, 45.1%, 41.6%) at the corresponding depths. Overall, deep soil and non-growing season SR represent important C emission sources; excluding them may therefore substantially overestimate net C sequestration potential.