Response of soil respiration to short-term changes in precipitation and nitrogen addition in a desert steppe

doi:10.1007/s40333-023-0068-6

Journal of Arid Land

2023, Vol. 15

Issue (9): 1084-1106 DOI: 10.1007/s40333-023-0068-6 CSTR: 32276.14.s40333-023-0068-6

Research article

Response of soil respiration to short-term changes in precipitation and nitrogen addition in a desert steppe

MA Jinpeng¹^,²^,³, PANG Danbo²^,³, HE Wenqiang²^,³, ZHANG Yaqi²^,³, WU Mengyao¹^,²^,³, LI Xuebin²^,³^,^*(

), CHEN Lin²^,³

¹College of Forestry and Prataculture, Ningxia University, Yinchuan 750021, China
²College of Ecological Environment, Ningxia University, Yinchuan 750021, China
³Breeding Base for State Key Laboratory of Land Degradation and Ecological Restoration in Northwest China, Ningxia University, Yinchuan 750021, China

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Abstract

Changes in precipitation and nitrogen (N) addition may significantly affect the processes of soil carbon (C) cycle in terrestrial ecosystems, such as soil respiration. However, relatively few studies have investigated the effects of changes in precipitation and N addition on soil respiration in the upper soil layer in desert steppes. In this study, we conducted a control experiment that involved a field simulation from July 2020 to December 2021 in a desert steppe in Yanchi County, China. Specifically, we measured soil parameters including soil temperature, soil moisture, total nitrogen (TN), soil organic carbon (SOC), soil microbial biomass carbon (SMBC), soil microbial biomass nitrogen (SMBN), and contents of soil microorganisms including bacteria, fungi, actinomyces, and protozoa, and determined the components of soil respiration including soil respiration with litter (R_S+L), soil respiration without litter (R_S), and litter respiration (R_L) under short-term changes in precipitation (control, increased precipitation by 30%, and decreased precipitation by 30%) and N addition (0.0 and 10.0 g/(m²·a)) treatments. Our results indicated that short-term changes in precipitation and N addition had substantial positive effects on the contents of TN, SOC, and SMBC, as well as the contents of soil actinomyces and protozoa. In addition, N addition significantly enhanced the rates of R_S+L and R_S by 4.8% and 8.0% (P<0.05), respectively. The increase in precipitation markedly increased the rates of R_S+L and R_S by 2.3% (P<0.05) and 5.7% (P<0.001), respectively. The decrease in precipitation significantly increased the rates of R_S+L and R_S by 12.9% (P<0.05) and 23.4% (P<0.001), respectively. In contrast, short-term changes in precipitation and N addition had no significant effects on R_L rate (P>0.05). The mean R_L/R_S+L value observed under all treatments was 27.63%, which suggested that R_L is an important component of soil respiration in the desert steppe ecosystems. The results also showed that short-term changes in precipitation and N addition had significant interactive effects on the rates of R_S+L, R_S, and R_L (P<0.001). In addition, soil temperature was the most important abiotic factor that affected the rates of R_S+L, R_S, and R_L. Results of the correlation analysis demonstrated that the rates of R_S+L, R_S, and R_L were closely related to soil temperature, soil moisture, TN, SOC, and the contents of soil microorganisms, and the structural equation model revealed that SOC and SMBC are the key factors influencing the rates of R_S+L, R_S, and R_L. This study provides further insights into the characteristics of soil C emissions in desert steppe ecosystems in the context of climate change, which can be used as a reference for future related studies.

Key words： soil respiration litter respiration nitrogen deposition soil carbon soil microorganisms climate change desert steppe ecosystems

Received: 24 February 2023 Published: 30 September 2023

Corresponding Authors: * LI Xuebin (E-mail: lixuebin@nxu.edu.cn)

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	MA Jinpeng
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	WU Mengyao
	LI Xuebin
	CHEN Lin

Cite this article:

MA Jinpeng, PANG Danbo, HE Wenqiang, ZHANG Yaqi, WU Mengyao, LI Xuebin, CHEN Lin. Response of soil respiration to short-term changes in precipitation and nitrogen addition in a desert steppe. Journal of Arid Land, 2023, 15(9): 1084-1106.

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http://jal.xjegi.com/10.1007/s40333-023-0068-6 OR http://jal.xjegi.com/Y2023/V15/I9/1084

Fig. 1 Variations in mean soil moisture and temperature (a), mean SMBN and SMBC (b), mean TN and SOC (c), and mean soil microbial content (d) under different treatments. SMBN, soil microbial biomass nitrogen; SMBC, soil microbial biomass carbon; TN, total nitrogen; SOC, soil organic carbon. N₀and N₁₀ indicate nitrogen (N) addition rates at 0.0 and 10.0 g/(m²·a), respectively. CK, IP, and DP represent the precipitation levels of the control, increased precipitation by 30%, and decreased precipitation by 30%, respectively. N₀×P indicates the treatments of CK+N₀, IP+N₀, and DP+N₀; N₁₀×P indicates the treatments of CK+N₁₀, IP+N₁₀ and DP+N₁₀; DP×N indicates the treatments of DP+N₀ and DP+N₁₀; CK×N indicates the treatments of CK+N₀ and CK+N₁₀; IP×N indicates the treatments of IP+N₀ and IP+N₁₀. Different lowercase letters indicate significant differences among different treatments for the same soil parameter at P<0.05 level based on the Duncan's test. * indicates significant differences among N addition treatments or among precipitation change treatments at P<0.05 level based on the Duncan's test; *** indicates significant differences among N addition treatments or among precipitation change treatments at P<0.001 level based on the Duncan's test; ns indicates no significant differences among N addition treatments or among precipitation change treatments at P>0.05 level based on the Duncan's test. Bars mean standard errors.

Table 1 Effects of changes in precipitation, nitrogen (N) addition, and their interaction (changes in precipitation×N addition) on soil parameters

Fig. 2 Diurnal dynamics in soil respiration with litter (R_S+L) in spring (a and b), summer (c and d), autumn (e and f), and winter (g and h) under different treatments. Small figures show the daily average R_S+L rate under different treatments. Different lowercase letters indicate significant differences among precipitation change treatments at P<0.05 level based on the Duncan's test; ns indicates no significant differences among N addition treatments at P>0.05 level based on the Duncan's test. Bars mean standard errors.

Fig. 3 Diurnal dynamics in soil respiration without litter (R_S) in spring (a and b), summer (c and d), autumn (e and f), and winter (g and h) under different treatments. Small figures show the daily average R_S rate under different treatments. Different lowercase letters indicate significant differences among precipitation change treatments at P<0.05 level based on the Duncan's test; * indicates significant differences among N addition treatments at P<0.05 level based on the Duncan's test; ns indicates no significant differences among N addition treatments at P>0.05 level based on the Duncan's test. Bars mean standard errors.

Fig. 4 Diurnal dynamics in litter respiration (R_L) in spring (a and b), summer (c and d), autumn (e and f), and winter (g and h) under different treatments. Small figures show the daily average R_L rate under different treatments. Different lowercase letters indicate significant differences among precipitation change treatments at P<0.05 level based on the Duncan's test; ns indicates no significant differences among N addition treatments at P>0.05 level based on the Duncan's test. Bars mean standard errors.

Fig. 5 Mean soil respiration (R_S+L, R_S, R_L) rate (a) and litter respiration contribution (R_L/R_S+L) (b) under different treatments. Different lowercase letters indicate significant differences among different precipitation change and N addition treatments at P<0.05 level based on the Duncan's test. *** indicates significant differences among N addition treatments or among precipitation change treatments at P<0.001 level based on the Duncan's test; ns indicates no significant differences among N addition treatments or among precipitation change treatments at P>0.05 level based on the Duncan's test. Bars mean standard errors.

Table 2 Effects of changes in precipitation, N addition, and their interaction on soil respiration with litter (R_S+L), soil respiration without litter (R_S), and litter respiration (R_L)

Fig. 6 Relationships of soil respiration (R_S+L, R_S, and R_L) with soil temperature (a, c, and e) and soil moisture (b, d, and f). T, soil temperature; W, soil moisture. The shaded part represents a 95% confidence interval.

Fig. 7 Correlation coefficients among soil respiration (R_S+L, R_S, and R_L), biotic factors (soil microorganisms) and abiotic factors (soil temperature, moisture, TN, SOC, SMBN, and SMBC, as well as changes in precipitation and N addition). *, significance at P<0.05 level; **, significance at P<0.01 level; ***, significance at P<0.001 level. Ellipses of different shapes indicate different significant sizes.

Fig. 8 Results of the structural equation model (SEM) reflecting the multivariate effects of biotic factors (soil microorganisms) and abiotic factors (soil temperature, moisture, SOC, and SMBC, as well as changes in precipitation and N addition) on R_S+L (a1 and a2), R_S (b1 and b2), and R_L (c1 and c2). Hyd-factor, soil hydrothermal factors; Soil C, soil carbon; χ²/df, cardinality freedom ratio; GFI, goodness-of-fit index; AGFI, adjusted goodness-of-fit index; RMSEA, root mean square error of approximation. Arrows show the effects of different factors on soil respiration. Values around the solid and dashed lines indicate positive and negative effects, respectively. The thickness of the line reflects the absolute value size of the correlation coefficient, for example, the thicker the line, the stronger the correlation. ^*, significance at P<0.05 level; ^**, significance at P<0.01 level; ^***, significance at P<0.001 level.

Fig. S1 Diurnal dynamics of soil temperature and moisture in spring (a and e), summer (b and f), autumn (c and g), and winter (d and h) under different treatments. N₀and N₁₀ indicate nitrogen (N) addition rates at 0.0 and 10.0 g/(m²·a), respectively. CK, IP, and DP indicate the precipitation levels of the control, increased precipitation by 30%, and decreased precipitation by 30%, respectively. N₀×P indicates the treatments of CK+N₀, IP+N₀, and DP+N₀; N₁₀×P indicates the treatments of CK+N₁₀, IP+N₁₀, and DP+N₁₀; DP×N indicates the treatments of DP+N₀ and DP+N₁₀; CK×N indicates the treatments of CK+N₀ and CK+N₁₀; IP×N indicates the treatments of IP+N₀ and IP+N₁₀. Bars mean standard errors.

Fig. S2 Seasonal dynamics in (a and b) soil respiration with litter (R_S+L), (c and d) soil respiration without litter (R_S), and (e and f) litter respiration (R_L) under different treatments. Bars mean standard errors.

Table S1 Characteristics of litter indices of the four typical plant species in the study area

Table S2 Composite functional parameters of soil respiration with litter (R_S+L), soil respiration without litter (R_S), and litter respiration (R_L) with soil temperature and moisture


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