生态环境学报2025,Vol.34Issue(9):1341-1350,10.DOI:10.16258/j.cnki.1674-5906.2025.09.002
基于随机森林和OCO-2遥感数据分析2023年中国连续时空xCO2变化特征
Analysis of China's Continuous Temporal xCO2 Change in 2023 Based on Random Forest and OCO-2 Remote Sensing Data
摘要
Abstract
Atmospheric carbon dioxide(CO2)is a key driver of global climate change.To better understand its role in the Earth's climate system,it is essential to precisely grasp the strategic layout for reducing pollution and carbon emissions and achieving regional peak CO2 levels.This comprehensive strategy not only helps reduce greenhouse gas emissions but also promotes effective environmental improvement and sustainable development,thereby effectively addressing the threats and challenges posed by global climate change.Using the Random Forest(RF)model and remote sensing data from the Orbiting Carbon Observatory-2(OCO-2)satellite,we constructed a detailed dataset of the column-averaged dry-air mole fraction of atmospheric CO2(xCO2)for continental China in 2023,featuring monthly temporal resolution and spatial continuity.Due to the high spatial resolution of the satellite swath data,the sample size was excessively large,with data points overly concentrated in certain regions,leading to potential overfitting during the simulation.Consequently,we resampled the observational data using an averaging method to match the spatial resolution of the auxiliary variables,resulting in a dataset resolution of 0.1°×0.1°.The processed sample data were then input into the model for analysis,employing eight feature variables as auxiliary data:Normalized Difference Vegetation Index(INDVI),wind speed components(u10,v10),temperature(t),total precipitation(Pt),nighttime light index(INL),elevation(HDEM),and land use and land cover(PLULC).These variables help us to comprehensively capture the various environmental factors affecting atmospheric CO2 concentrations.In other words,the more frequently a particular attribute is used during the model building,the higher its importance.To verify the accuracy of the OCO-2 remote sensing data,we extracted observational data within a±5° radius around the Xianghe station of the Total Carbon Column Observation Network(TCCON)for comparative analysis and analyzed the contribution rates of auxiliary variables in the model.In this study,a simple linear regression analysis method was used to analyze the change in correlation relationship significance(p)and slope(b)to analyze the trend of atmospheric xCO2 concentration from April to August 2023.In addition,a feature importance analysis was conducted to evaluate the significance of each independent variable in the model.The results demonstrated a significant correlation between the OCO-2 satellite remote sensing data and ground-based observational network data,with a coefficient of determination(R2)of 0.902 and a mean squared error(σMSE)of 1.45×10-6.Analysis of feature importance revealed associations between xCO2 concentration and factors related to the natural environment,meteorological conditions,and anthropogenic activities.Among these factors,the effects of HDEM and t on the variation in xCO2 concentration were the most pronounced.This suggests that the distribution of atmospheric CO2 is significantly regulated by altitude under different topographic conditions,which may be closely related to variations in atmospheric pressure,surface fluxes,and the structure of the atmospheric boundary layer.Changes in temperature directly influence the dynamic balance of carbon sources and sinks at the surface,thereby affecting the spatiotemporal characteristics of xCO2.In contrast,the contributions of PLULC and Pt to the variation in xCO2 were relatively minor.Additionally,while precipitation plays an important role in regulating vegetation growth and soil carbon release,its direct driving effect on xCO2 concentration was not prominent in this study.Further model analysis showed an R2 exceeding 0.82 and an σMSE below 0.48×10-6 between OCO-2 data and RF model predictions,with a mean bias error(E)less than 0.02×10-6,indicating high model fitting accuracy and strong predictive capability.The spatiotemporal distribution characteristics of atmospheric xCO2 in China were also analyzed.Temporally,xCO2 peaked in April and reached its lowest level in August.The concentration trend followed the order:Spring>Winter>Autumn>Summer,exhibiting distinct seasonality.Overall,as temperatures rise in spring,plants enter their growth season,enhancing photosynthesis and fixing significant amounts of atmospheric CO2.However,this period also sees the melting of winter snow and thawing of soil,which releases carbon from the soil and causes xCO2 concentrations to rise further.In summer,plants grow vigorously,with intense photosynthesis that fixes large amounts of CO2.Due to plant transpiration,the air becomes relatively humid,leading to noticeable changes in local xCO2 concentrations.In autumn,as temperatures drop and daylight hours decrease,plant growth slows,leaves fall,and photosynthesis decreases.The decomposition of fallen leaves and dead branches releases some of the fixed carbon,causing atmospheric xCO2 concentrations to rise.In winter,low temperatures and shorter days,along with increased heating demand and fossil fuel consumption,lead to a continuous increase in the xCO2 concentrations.Spatially,atmospheric xCO2 concentrations generally follow a pattern of being lower in the west and higher in the east,and lower in the north,and higher in the south.The higher the latitude,the greater the seasonal variation,and different temperature zones exhibit variations in the xCO2 distribution.Based on the analysis of atmospheric xCO2 concentration spatial distribution changes,it was found that the North China Plain has higher atmospheric xCO2 concentrations,with the highest levels in Beijing,Tianjin,and Anhui.In Northeast China,atmospheric xCO2 concentrations exhibit pronounced seasonal changes.From April to August,the significance analysis revealed that,apart from no significant changes in atmospheric xCO2 concentrations over the Qinghai-Tibet Plateau and the Yunnan-Guizhou Plateau,other regions showed significant variations.Notably,the most significant changes were observed in Heilongjiang,followed by eastern Xizang,Jilin,the Bohai Sea area,and the northern slopes of the Tianshan Mountains in the Xinjiang region.In high-cold ecosystems,even under the backdrop of climate warming,the amount of fixed carbon exceeds the amount released.These ecosystems continue to play a crucial role as carbon sinks,owing to enhanced plant adaptation.This study provides a crucial basis for accurately estimating regional atmospheric CO2 concentrations in China and offers new perspectives for understanding the carbon cycle processes in terrestrial ecosystems.The research results can help establish a more accurate model,predict the future trend of carbon dioxide change,provide a reference for the refined monitoring of urban carbon emissions,and provide strong geospatial information support for the implementation of the"carbon peak and carbon neutral"strategy at the regional level.关键词
xCO2/随机森林/时空变化/OCO-2/卫星遥感Key words
xCO2/random forests/spatial and temporal variations/OCO-2/satellite remote sensing分类
资源环境引用本文复制引用
吴锡言,李维军,卡那特,彭玉杰..基于随机森林和OCO-2遥感数据分析2023年中国连续时空xCO2变化特征[J].生态环境学报,2025,34(9):1341-1350,10.基金项目
新疆建设兵团重点研发计划(2023AB036) (2023AB036)
新疆建设兵团重点科技攻关(2024AB076) (2024AB076)
2023年度师市科技计划(第二批社会发展类)(2023ZDSF11) (第二批社会发展类)
