植物生态学报 ›› 2003, Vol. 27 ›› Issue (4): 441-447.DOI: 10.17521/cjpe.2003.0063

• 论文 • 上一篇    下一篇

温带草原11个植物群落夏秋土壤呼吸对气温变化的响应

陈全胜,李凌浩,韩兴国,阎志丹,王艳芬,张焱,袁志友,唐芳   

  • 发布日期:2015-11-04
  • 通讯作者: 陈全胜

Responses of Soil Respiration to Temperature in Eleven Communities in Xilingol Grassland, Inner Mongolia

CHEN Quan-Sheng, LI Ling Hao, HAN Xing-Guo, YAN Zhi-Dan, WANG Yan-Fen, ZHANG Yan, YUAN Zhi-You, TANG Fang   

  • Published:2015-11-04
  • Contact: SUN Wei

摘要:

在夏秋季节,采用碱液吸收法对锡林郭勒草原11个群落的土壤呼吸进行了测定,比较和分析了各群落土壤呼吸的季节动态、平均呼吸速率、土壤呼吸对气温变化的响应。结果表明:1)各群落土壤呼吸有明显的季节变化,其动态与气温大体一致,但不完全同步; 2)生长季各群落平均呼吸速率介于565.07~1 349.56 mg C·m-2·d-1之间,总体差异极显著,各群落平均呼吸速率与平均气温无显著相关关系;3)指数模型能较好地表示土壤呼吸对温度变化的响应,温度能在一定程度上解释土壤呼吸的季节变化,但温度较低时模型的拟合好于温度较高时;4)各群落的Q10值介于1.47~1.84之间,与各群落的平均气温亦无显著相关关系,小麦群落的Q10高于所有草地群落,说明土地利用方式对土壤呼吸的温度敏感性有影响。

Abstract:

Soil surface carbon dioxide flux, the sum of plant and microbial respiration, is an important component of the carbon cycle of terrestrial ecosystems. Temperature is a key factor that regulates many terrestrial biogeochemical processes, such as soil respiration. Numerous studies show that soil respiration increases with temperature, creating a positive feedback to global warming. Accurately quantifying the relationship between soil respiration and temperature is necessary, because it will help to develop mechanisms of the feedback, which will aid in predicting the tendency of global change. In order to determine the law of soil respiration dynamics driven by temperature, and to detect the sensitivity of soil respiration in response to temperature in different communities of temperate grassland, in summer and autumn, we measured soil respiration in eleven communities using the alkali absorption method. We examined seasonal patterns of soil respiration, average respiration rate and responses of soil respiration to temperature. All the communities were located in Xilin River Basin, which has a typical temperate and semi-arid climate.The seasonal variations of soil respiration were similar to those of temperature, but were not completely consistent with each other. The highest value of soil respiration was in summer (June to Aug.). Average soil respiration rates of all communities varied from 565.07 mg C·m-2·d-1 to 1 349.56 mg C·m-2·d-1, and the difference was significant (p<0.001). Respiration was greatest in wet mixed grasses community and least in Caragana stenophylla community. There was no notable relationship between average soil respiration and air temperature in all eleven communities, though relation of soil respiration and temperature could be described well by exponential functions for each community (R2 = 0.330 5 - 0.731 2, p<0.000 1-0.022 0). The modeling was better at lower temperature than at higher. Q10 values of all communities were between 1.47 and 1.84, which were similar to or a little higher than the value in global scale. The Q10 value of wheat community was higher than that of other communities, which implied that land use could affect the sensitivity of soil respiration to temperature, and cultivation of the soil in grassland might be a CO2 source for atmosphere along with global warming.