线性和指数回归方法对土壤呼吸CO2扩散速率估算的影响

doi:10.17521/cjpe.2007.0046

摘要/Abstract

摘要：

理论上,土壤呼吸通量的量值可以通过观测土壤呼吸CO₂扩散速率(∂c/∂t)计算得到。但是为获得∂c/∂t,通常须允许土壤呼吸箱内CO₂浓度升高,因此,如何估算外界大气CO₂浓度条件下的∂c/∂t是土壤呼吸观测技术的关键,关系到观测结果的准确性。通常∂c/∂t的估算会受土壤表层大气CO₂扩散梯度(即土壤呼吸箱内CO₂扩散梯度和大气CO₂浓度昼夜变化)的影响。目前,线性回归方法是土壤呼吸观测中估算∂c/∂t的基本方法。然而,常用的线性回归方法会低估∂c/∂t,而指数回归方法则可以准确地估算∂c/∂t。夜间∂c/∂t的变化与大气CO₂浓度之间存在非常明显的负相关关系。夜间土壤表层大气CO₂扩散梯度的减小导致线性回归方法明显低估∂c/∂t。∂c/∂t的昼夜变化过程存在明显的非对称性现象,而指数回归方法可以更好地描述∂c/∂t昼夜变化的非对称性响应。

关键词: 土壤呼吸, CO₂扩散梯度, CO₂扩散速率, 线性回归, 指数回归, 日变化

Abstract:

Aims Soil CO₂ flux is driven primarily by the CO₂ diffusion gradient across the soil surface. Ideally, the soil CO₂ flux measurement should be made without affecting the diffusion gradient across the soil surface. With the closed chamber system, the soil CO₂ diffusion rate (∂c/∂t) is required to estimate the soil CO₂ flux. To obtain the ∂c/∂t, the chamber CO₂ concentration must be allowed to rise. Consequently, the ∂c/∂t will be affected by the CO₂ diffusion gradient across the soil surface because of the decreased CO₂ diffusion gradient in the soil chamber. Additionally, the ∂c/∂t will also be affected by the diurnal variation of the CO₂ concentration across the soil surface. Our objective was to compare linear and exponential fitting methods to estimate ∂c/∂t.
Methods Currently, the ∂c/∂t is commonly estimated using linear fitting regression. Instead of using the linear fitting method, an exponential fitting method is used to fit the time series of chamber CO₂ concentration adopted in the LI-8100 automated soil CO₂ flux system.
Important findings The ∂c/∂t estimated from the linear slopes was consistently underestimated as compared to that from exponential initial slopes. Nighttime ∂c/∂t was significantly negatively correlated with soil surface CO₂ concentration, suggesting that the decreased CO₂ diffusion gradient across the soil surface strongly influences the ∂c/∂t. For the closed-chamber method, linear curve fitting significantly underestimated the ∂c/∂t rate during the nighttime. These results demonstrated the importance of estimating the ∂c/∂t at ambient soil surface CO₂ concentration. The response of the ∂c/∂t to air temperature exhibited significant asymmetry characteristic, showing that it is a better way for exponential fitting to make long-term and continuous soil CO₂ flux measurement to elucidate the magnitudes and processes of soil CO₂ flux in the typical terrestrial ecosystem.

Key words: soil respiration, CO₂ diffusion gradient, CO₂ diffusion rate, linear fit, exponential fit, diurnal variation

温学发, 孙晓敏, 刘允芬, 李晓波. 线性和指数回归方法对土壤呼吸CO₂扩散速率估算的影响. 植物生态学报, 2007, 31(3): 380-385. DOI: 10.17521/cjpe.2007.0046

WEN Xue-Fa, SUN Xiao-Min, LIU Yun-Fen, LI Xiao-Bo. EFFECTS OF LINEAR AND EXPONENTIAL FITTING ON THE INITIAL RATE OF CHANGE IN CO₂ CONCENTRATION ACROSS THE SOIL SURFACE. Chinese Journal of Plant Ecology, 2007, 31(3): 380-385. DOI: 10.17521/cjpe.2007.0046

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链接本文: https://www.plant-ecology.com/CN/10.17521/cjpe.2007.0046

https://www.plant-ecology.com/CN/Y2007/V31/I3/380

图/表 5

图1 指数和线性回归方法对土壤呼吸CO2扩散速率(?c/?t)的影响

Fig.1 Impacts of exponential and linear fit on the initial rate of change in the CO2 concentration across the soil surface a: 土壤呼吸箱内CO2浓度的变化过程 Variations of CO2 concentration in the soil respiration chamber b: 材料与方法中试验处理1) Experiment 1) described in Material and Methods

图2 测量时间对土壤呼吸CO2扩散速率(?c/?t)的影响

Fig.2 Impacts of different measuring periods on the initial rate of change in CO2 concentration (?c/?t) across the soil surface

图3 指数和线性回归估算的土壤呼吸CO2扩散速率(?c/?t)和大气CO2浓度的日变化特征

Fig.3 Diurnal variation of CO2 concentration and the initial rate of change in the CO2 concentration (?c/?t) by the exponential and linear fit across the soil surface

图4 昼夜CO2扩散梯度变化对土壤呼吸CO2扩散速率(?c/?t)的影响 a和c指白天数据 b和d指夜间数据

Fig.4 Impact of the diurnal CO2 diffusion gradient on the initial rate of change in CO2 concentration (?c/?t) across the soil surface a and c refer to daytime data b and d refer to nighttime data

图5 土壤呼吸CO2扩散速率(?c/?t)对温度昼夜变化响应的非对称性响应特征 a、b和c分别代表图3中第一天、第二天和第三天的日变化数据 d代表图3中所有的日变化数据

Fig.5 Diurnal asymmetry of the initial rate of change in CO2 concentration (?c/?t) in response to air temperature across the soil surface a, b and c refer to the data on the 1st, 2nd and 3rd day, respectively, in Fig. 3 d refers to all data in Fig. 3

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线性和指数回归方法对土壤呼吸CO₂扩散速率估算的影响

EFFECTS OF LINEAR AND EXPONENTIAL FITTING ON THE INITIAL RATE OF CHANGE IN CO₂ CONCENTRATION ACROSS THE SOIL SURFACE

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