Abstract
Severe droughts and changing precipitation patterns could alter the biogeochemical properties of the soil, affecting soil carbon cycles in forest ecosystems. A throughfall exclusion (TFE) experiment was conducted in a continental climate coniferous stand in Gangwon Province, Korea, to examine the effects of excluding rainfall on total soil respiration (SR), heterotrophic soil respiration (HR), autotrophic soil respiration (AR), sapling diameter growth, and soil bacterial communities from July 2016 to October 2017. The soil water content (SWC) was significantly decreased by the exclusion of the throughfall, resulting in changes in the bacterial communities, and subsequently a decrease in HR. Although AR did not present significant differences between the control and TFE plots, the rate of sapling growth was significantly lower in the TFE plots compared with that in the control plots. An exponential function relating SR to soil temperature accounted for 0.61% and 0.82% of the variance in SR in the control and TFE plots, respectively (Q10 = 2.48 and 2.86, respectively). Furthermore, a multivariate nonlinear model based on soil temperature and SWC explained 0.89% and 0.88% of the variance in SR in the control and TFE plots, respectively. When soil temperature was high, SR showed high fluctuations due to SWC variation. However, when SWC was low, we detected relatively small fluctuations in SR due to soil temperature. The results of this study show that the activity of soil microbial and root respiration during the growing season may be lower under future drought conditions.
Highlights
Cumulative greenhouse gas emissions, those of carbon dioxide, lead to climate change effects that manifest in multiple forms, such as global warming and drought [1]
In the throughfall exclusion (TFE) experiment, the drought simulation resulted in no significant differences in soil temperatures between the control and TFE plots, the soil water content was significantly lower in the TFE plots compared with that of the control plots
Due to the greenhouse effect of the roof, we cannot draw the conclusion that the reduction in autotrophic soil respiration (AR) and sapling growth are the only effects of drought simulation
Summary
Cumulative greenhouse gas emissions, those of carbon dioxide, lead to climate change effects that manifest in multiple forms, such as global warming and drought [1]. Total soil respiration (SR) is the second-largest contributor to the global carbon flux [2]. Even subtle changes in SR may affect global carbon dynamics. To understand the impact of climate change on forest ecosystems, it is important to generate accurate estimates of the carbon dynamics in these systems, given that changes in ST and SWC impact on forest carbon cycles, while causing structural alterations in the forest [1,6]. Q10 values (temperature sensitivity) are the most widely used indices for assessing the responses of soil respiration to temperature [7], and the global median value of Q10 has been reported to be 2.4 [8]. With respect to forest ecosystems, Q10 values can vary considerably, depending on forest type and age, climate, and season [7,9,10]
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