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《地球科学与环境学报》[ISSN:1672-6561/CN:61-1423/P]

Issue:

2024年第02期

Page:

180-195

Research Field:

环境与可持续发展

Publishing date:

Info

Title:

Impacts ofTypical Human Activities onPM_2.5 Concentrations in GuanzhongPlain Urban Agglomeration,China

Author(s):

LI Chang-yan-ji¹; 2;  GAO Mei-ling¹; 2; 3*;  LI Zhen-hong¹; 2; 3

(1. School of Geological Engineering and Geomatics, Chang'an University, Xi'an 710054, Shaanxi, China; 2. Big DataCenter for Geosciences and Satellites, Chang'an University, Xi'an 710054, Shaanxi, China; 3. Key Laboratory of Ecological Geology and Disaster Prevention of Ministry of Natural Resources,Chang'an University, Xi'an 710054, Shaanxi, China)

Keywords:

driving factor;  spatio-temporal evolution;  PM_2.5 concentration;  spatial autocorrelation;  geographic detector;  multi-scale geographically weighted regression model;  Guanzhong Plain

PACS:

X513

DOI:

10.19814/j.jese.2023.09031

Abstract:

In response to a public health emergency,it provides a unique natural experimental environment to study the effects of human activities on PM_2.5 concentrations. However there is a lack of attention on how the distribution and drivers of PM_2.5 concentrations in Guanzhong Plain urban agglomeration changed during the implementation of mobility restriction measuresin February to March, 2020.Based on the remotely-sensed retrieved PM_2.5 data from 2018 to 2020, the spatial autocorrelation analysis, geographic detector and multi-scale geographically weighted regression(MGWR)model were used to analyze the spatial and temporal evolution of PM_2.5 concentrations and its driving factors in Guanzhong Plain urban agglomeration during the implementation ofmobility restriction measuresin February to March, 2020. The results show that ① PM_2.5 concentrations decrease significantly from February to March in 2020, hot spots decrease in February, and cold spots decreasein March. ② Compared with the same periodin 2018 and 2019, all anthropogenic factors have the lowest explanatory power for PM_2.5 concentrations in Guanzhong Plain urban agglomerationin February, 2020, and the natural factors have a higher explanatory power; among them, the explanatory power of plantpoint of interestdistribution(POI_D)and road network kernel density(RD)decrease the most compared with the average explanatory power in the same period, which are 20.3% and 38.6%, respectively. The explanatory power of the two-factor interaction effect of all human factors is the lowestin February, 2020. ③ The scale of effect of all anthropogenic factors on PM_2.5 concentrations in Guanzhong Plain urban agglomeration is the smallestin February, 2020, and when the intensity of each anthropogenic factor is averaged over different periods, PM_2.5 concentrations are more likely to be lowered during the implementation ofmobility restriction measures, but the intensity of the prevention and control of PM_2.5 concentrations in the eastern part of the region needs to be increased.

References:

[1] 张永年,潘竟虎.基于DMSP/OLS数据的中国碳排放时空模拟与分异格局[J].中国环境科学,2019,39(4):1436-1446.
ZHANG Yong-nian,PAN Jing-hu.Spatio-temporal Simulation and Differentiation Pattern of Carbon Emissions in China Based on DMSP/OLS Nighttime LightData[J].China Environmental Science,2019,39(4):1436-1446.
[2]慕 航,何 超,阮秋明,等.“一带一路”沿线国家PM_2.5污染与人口暴露风险的时空分布特征[J].环境科学学报,2021,41(6):2229-2240.
MU Hang,HE Chao,RUAN Qiu-ming,et al.Spatiotemporal Distribution Characteristics and Population Exposure Risks to PM_2.5 in Countries Along the Belt and Road[J].Acta Scientiae Circumstantiae,2021,41(6):2229-2240.
[3]王 利,徐翠玲,徐 甫,等.2011～2020年华北平原气溶胶光学厚度时空分布特征及潜在源分析[J].地球科学与环境学报,2021,43(6):1018-1032.
WANG Li,XU Cui-ling,XU Fu,et al.Temporal and Spatial Distribution Characteristics,and Potential Source Analysis of Aerosol Optical Depth in North China Plain from 2011 to 2020[J].Journal of Earth Sciences and Environment,2021,43(6):1018-1032.
[4]南国卫,孙 虎,朱一梅.陕西省PM_2.5时空分布规律及其影响因素[J].环境科学研究,2018,31(5):834-843.
NAN Guo-wei,SUN Hu,ZHU Yi-mei.Spatial and Temporal Characteristics of PM_2.5 in Shaanxi Province and Its Driving Factors[J].Research of Environmental Sciences,2018,31(5):834-843.
[5]苟爱萍,李皖新,王江波.重庆市绿色空间景观格局与PM_2.5浓度时空相关性[J].地球科学与环境学报,2024,46(1):25-37.
GOU Ai-ping,LI Wan-xin,WANG Jiang-bo.Spatiotemporal Correlation Between Green Space Landscape Pattern and PM_2.5 Concentration in Chongqing City, China[J].Journal of Earth Sciences and Environment,2024,46(1):25-37.
[6]CHEN T,HE J,LU X W,et al.Spatial and Temporal Variations of PM_2.5 and Its Relation to Meteorological Factors in the Urban Area of Nanjing,China[J].International Journal of Environmental Research and Public Health,2016,13(9):921.
[7]TSAI Y I,KUO S C,LEE W J,et al.Long-term Visibility Trends in One Highly Urbanized,One Highly Industrialized,and Two Rural Areas of Taiwan[J].Science of the Total Environment,2007,382(2/3):324-341.
[8]廖晓农,张小玲,王迎春,等.北京地区冬夏季持续性雾-霾发生的环境气象条件对比分析[J].环境科学,2014,35(6):2031-2044.
LIAO Xiao-nong,ZHANG Xiao-ling,WANG Ying-chun,et al.Comparative Analysis on Meteorological Condition for Persistent Haze Cases in Summer and Winter in Beijing[J].Environmental Science,2014,35(6):2031-2044.
[9]林巧莺,陈永山.我国城市冬季PM_2.5空间特征及其人为影响因子[J].生态与农村环境学报,2015,31(4):460-465.
LIN Qiao-ying,CHEN Yong-shan.Spatial Variation of PM_2.5 in Cities in Winter and Anthropogenic Influencing Factors in China[J].Journal of Ecology and Rural Environment,2015,31(4):460-465.
[10]沈利娟,王红磊,赵天良,等.第十四届全运会大气污染物减排措施对西安市气溶胶中水溶性离子和含碳组分的影响[J].地球科学与环境学报,2024,46(1):38-53.
SHEN Li-juan,WANG Hong-lei,ZHAO Tian-liang,et al.Influence of Air Pollutant Reduction Measures on Aerosol Water-soluble Ions and Carbonaceous Components During the 14th National Games in Xi'an City of Shaanxi,China[J].Journal of Earth Sciences and Environment,2024,46(1):38-53.
[11]周 磊,武建军,贾瑞静,等.京津冀PM_2.5时空分布特征及其污染风险因素[J].环境科学研究,2016,29(4):483-493.
ZHOU Lei,WU Jian-jun,JIA Rui-jing,et al.Investigation of Temporal-spatial Characteristics and Underlying Risk Factors of PM_2.5 Pollution in Beijing-Tianjin-Hebei Area[J].Research of Environmental Sciences,2016,29(4):483-493.
[12]LIN G,FU J Y,JIANG D,et al.Spatio-temporal Variation of PM_2.5 Concentrations and Their Relationship with Geographic and Socioeconomic Factors in China[J].International Journal of Environmental Research and Public Health,2014,11(1):173-186.
[13]周亚端,朱宽广,黄 凡,等.新冠肺炎疫情期间湖北省大气污染物减排效果评估[J].环境科学与技术,2020,43(3):228-236.
ZHOU Ya-duan,ZHU Kuan-guang,HUANG Fan,et al.Emission Reductions and Air Quality Improvements During the COVID-19 Pandemic in Hubei Province[J].Environmental Science & Technology,2020,43(3):228-236.
[14]GAN W T,ZHOU M Y,CHENG Y R,et al.Air Quality and the COVID-19 Outbreak in China[J].Allergologia et Immunopathologia,2021,49(1):165-167.
[15]王申博,范相阁,和 兵,等.河南省春节和疫情影响情景下PM_2.5组分特征[J].中国环境科学,2020,40(12):5115-5123.
WANG Shen-bo,FAN Xiang-ge,HE Bing,et al.Chemical Composition Characteristics of PM_2.5 in Henan Province During the Spring Festival and COVID-19 Outbreak[J].China Environmental Science,2020,40(12):5115-5123.
[16]乐 旭,雷亚栋,周 浩,等.新冠肺炎疫情期间中国人为碳排放和大气污染物的变化[J].大气科学学报,2020,43(2):265-274.
YUE Xu,LEI Ya-dong,ZHOU Hao,et al.Changes of Anthropogenic Carbon Emissions and Air Pollutants During the COVID-19 Epidemic in China[J].Transactions of Atmospheric Sciences,2020,43(2):265-274.
[17]HAN B S,PARK K,KWAK K H,et al.Air Quality Change in Seoul,South Korea Under COVID-19 Social Distancing:Focusing on PM_2.5[J].International Journal of Environmental Research and Public Health,2020,17(17):6208.
[18]MA C J,KANG G U.Air Quality Variation in Daegu,Korea During the Outbreak of COVID-19 and Its Health Risk Assessment[J].Asian Journal of Atmospheric Environment,2020,14(3):253-262.
[19]LOU B W,BARBIERI D M,PASSAVANTI M,et al.Air Pollution Perception in Ten Countries During the COVID-19 Pandemic[J].Ambio,2022,51(3):531-545.
[20]HUANG R J,ZHANG Y L,BOZZETTI C,et al.High Secondary Aerosol Contribution to Particulate Pollution During Haze Events in China[J].Nature,2014,514:218-222.
[21]杜虹萱,任丽红,赵明升,等.2017～2018年冬季菏泽大气PM_2.5中金属元素特征及健康风险评估[J].环境科学,2024,45(3):1361-1370.
DU Hong-xuan,REN Li-hong,ZHAO Ming-sheng,et al.Characterization of Metal Elements in Atmospheric PM_2.5 and Health Risk Assessment in Heze in Winter from 2017 to 2018[J].Environmental Science,2024,45(3):1361-1370.
[22]张小曳,徐祥德,丁一汇,等.2013～2017年气象条件变化对中国重点地区PM_2.5质量浓度下降的影响[J].中国科学:地球科学,2020,50(4):483-500.
ZHANG Xiao-ye,XU Xiang-de,DING Yi-hui,et al.The Impact of Meteorological Changes from 2013 to 2017 on PM_2.5 Mass Reduction in Key Regions in China[J].Science China:Earth Sciences,2020,50(4):483-500.
[23]赵 雪,沈楠驰,李令军,等.COVID-19疫情期间京津冀大气污染物变化及影响因素分析[J].环境科学,2021,42(3):1205-1214.
ZHAO Xue,SHEN Nan-chi,LI Ling-jun,et al.Analysis of Changes and Factors Influencing Air Pollutants in the Beijing-Tianjin-Hebei Region During the COVID-19 Pandemic[J].Environmental Science,2021,42(3):1205-1214.
[24]王爱平,朱 彬,秦 玮,等.新冠疫情严控期间南京市空气质量[J].中国环境科学,2021,41(7):3088-3095.
WANG Ai-ping,ZHU Bin,QIN Wei,et al.Air Quality in Nanjing During COVID-19 Lockdown Period[J].China Environmental Science,2021,41(7):3088-3095.
[25]刘跃斌,张 远,张逸冰,等.邯郸市新冠疫情前后空气质量指数(AQI)对比与疫情防控期间大气污染特征分析[J].环境化学,2021,40(12):3743-3754.
LIU Yue-bin,ZHANG Yuan,ZHANG Yi-bing,et al.Comparison of Air Quality Index(AQI)Before and After COVID-19 in Handan City and Analysis of Air Pollution Characteristics During COVID-19 Prevention and Control[J].Environmental Chemistry,2021,40(12):3743-3754.
[26]LIU C W,HUANG Z W,HUANG J P,et al.Comparison of PM_2.5 and CO₂ Concentrations in Large Cities of China During the COVID-19 Lockdown[J].Advances in Atmospheric Sciences,2022,39(6):861-875.
[27]邱雨露,陈 磊,朱 佳,等.COVID-19管控期间气象条件变化对京津冀PM_2.5浓度影响[J].环境科学,2022,43(6):2831-2839.
QIU Yu-lu,CHEN Lei,ZHU Jia,et al.Impacts of Changes in Meteorological Conditions During COVID-19 Lockdown on PM_2.5 Concentrations over the Jing-Jin-Ji Region[J].Environmental Science,2022,43(6):2831-2839.
[28]WEN L Y,YANG C,LIAO X L,et al.Investigation of PM_2.5 Pollution During COVID-19 Pandemic in Guangzhou,China[J].Journal of Environmental Sciences,2022,115(5):443-452.
[29]CHU B W,ZHANG S P,LIU J,et al.Significant Concurrent Decrease in PM_2.5 and NO₂ Concentrations in China During COVID-19 Epidemic[J].Journal of Environmental Sciences,2021,99(1):346-353.
[30]缪 青,杨 倩,吴也正,等.COVID-19管控期间苏州市PM_2.5中金属元素浓度变化及来源解析[J].环境科学,2022,43(6):2851-2857.
MIAO Qing,YANG Qian,WU Ye-zheng,et al.Concentration Variation and Source Analysis of Metal Elements in PM_2.5 During COVID-19 Control in Suzhou[J].Environmental Science,2022,43(6):2851-2857.
[31]逯世泽,史旭荣,薛文博,等.新冠肺炎疫情期间气象条件和排放变化对PM_2.5的影响[J].环境科学,2021,42(7):3099-3106.
LU Shi-ze,SHI Xu-rong,XUE Wen-bo,et al.Impacts of Meteorology and Emission Variations on PM_2.5 Concentration Throughout the Country During the 2020 Epidemic Period[J].Environmental Science,2021,42(7):3099-3106.
[32]WEI J,LI Z Q,LYAPUSTIN A,et al.Reconstructing 1-km-resolution High-quality PM_2.5 Data Records from 2000 to 2018 in China:Spatiotemporal Variations and Policy Implications[J].Remote Sensing of Environment,2021,252:112136.
[33]WEI J,LI Z Q,CRIBB M,et al.Improved 1 km Resolution PM_2.5 Estimates Across China Using Enhanced Space-time Extremely Randomized Trees[J].Atmospheric Chemistry and Physics,2020,20(6):3273-3289.
[34]WANG X,WAHIDUZZAMAN M,YEASMIN A.A Kernel Density Estimation Approach and Statistical Generalized Additive Model of Western North Pacific Typhoon Activities[J].Atmosphere,2022,13(7):1128.
[35]王子峤,李叙勇.基于核密度估计的城市基础要素与街尘营养元素含量特征关联[J].环境科学,2022,43(2):867-877.
WANG Zi-qiao,LI Xu-yong.Identifying Relationship Between Nutrient Contents in Road-deposited Sediment and Urban Basic Elements Based on Kernel Density Estimation[J].Environmental Science,2022,43(2):867-877.
[36]XIE Y H,WENG Q H.World Energy Consumption Pattern as Revealed by DMSP-OLS Nighttime Light Imagery[J].GIScience & Remote Sensing,2016,53(2):265-282.
[37]吴健生,牛 妍,彭 建,等.基于DMSP/OLS夜间灯光数据的1995～2009年中国地级市能源消费动态[J].地理研究,2014,33(4):625-634.
WU Jian-sheng,NIU Yan,PENG Jian,et al.Research on Energy Consumption Dynamic Among Prefecture-level Cities in China Based on DMSP/OLS Nighttime Light[J].Geographical Research,2014,33(4):625-634.
[38]张松林,张 昆.全局空间自相关Moran指数和G系数对比研究[J].中山大学学报(自然科学版),2007,46(4):93-97.
ZHANG Song-lin,ZHANG Kun.Comparison Between General Moran's Index and Getis-ord General G of Spatial Autocorrelation[J].Acta Scientiarum Naturalium Universitatis Sunyatseni,2007,46(4):93-97.
[39]陈彦光.基于Moran统计量的空间自相关理论发展和方法改进[J].地理研究,2009,28(6):1449-1463.
CHEN Yan-guang.Reconstructing the Mathematical Process of Spatial Autocorrelation Based on Moran's Statistics[J].Geographical Research,2009,28(6):1449-1463.
[40]王劲峰,徐成东.地理探测器:原理与展望[J].地理学报,2017,72(1):116-134.
WANG Jin-feng,XU Cheng-dong.Geodetector:Principle and Prospective[J].Acta Geographica Sinica,2017,72(1):116-134.
[41]徐 勇,郭振东,郑志威,等.运用地理探测器研究京津冀城市群PM_2.5浓度变化及影响因素[J].环境科学研究,2023,36(4):649-659.
XU Yong,GUO Zhen-dong,ZHENG Zhi-wei,et al.Study of the PM_2.5 Concentration Variation and Its Influencing Factors in the Beijing-Tianjin-Hebei Urban Agglomeration Using Geodetector[J].Research of Environmental Sciences,2023,36(4):649-659.
[42]罗逸臻,黄远程,王 涛.关中平原城市群生态环境质量时空变化特征及其驱动力[J].地球科学与环境学报,2023,45(6):1316-1329.
LUO Yi-zhen,HUANG Yuan-cheng,WANG Tao.Spatial-temporal Variation Characteristics of Ecological Environment Quality and Their Driving Forces in Guanzhong Plain Urban Agglomeration,China[J].Journal of Earth Sciences and Environment,2023,45(6):1316-1329.
[43]沈体雁,于瀚辰,周 麟,等.北京市二手住宅价格影响机制:基于多尺度地理加权回归模型(MGWR)的研究[J].经济地理,2020,40(3):75-83.
SHEN Ti-yan,YU Han-chen,ZHOU Lin,et al.On Hedonic Price of Second-hand Houses in Beijing Based on Multi-scale Geographically Weighted Regression:Scale Law of Spatial Heterogeneity[J].Economic Geography,2020,40(3):75-83.
[44]刘 珺,俞博云,杨文府.多尺度地理加权回归模型支持下的汾河流域生态系统服务关系演化机理研究[J].遥感学报,2023,27(7):1667-1679.
LIU Jun,YU Bo-yun,YANG Wen-fu.Evolution Mechanism of Ecosystem Service Relationship in the Fenhe River Basin Based on Multiscale Geographically Weighted Regression[J].National Remote Sensing Bulletin,2023,27(7):1667-1679.
[45]王 强,崔璐明,鄢慧丽.黄河流域区域经济差异影响因素的空间异质性:基于MGWR模型的实证研究[J].地域研究与开发,2023,42(2):7-13.
WANG Qiang,CUI Lu-ming,YAN Hui-li.Spatial Heterogeneity of Driving Factors of the Regional Economic Disparity in the Yellow River Basin:A Multiscale Geographically Weighted Regression Approach[J].Areal Research and Development,2023,42(2):7-13.
[46]GB 3095—2012,环境空气质量标准[S].
GB 3095—2012,AmbientAir Quality Standards[S].
[47]王妘涛,张 强,温肖宇,等.运城市PM_2.5时空分布特征和潜在源区季节分析[J].环境科学,2022,43(1):74-84.
WANG Yun-tao,ZHANG Qiang,WEN Xiao-yu,et al.Spatiotemporal Distribution and Seasonal Characteristics of Regional Transport of PM_2.5 in Yuncheng City[J].Environmental Science,2022,43(1):74-84.
[48]周志衡,周廷刚,秦 宁.中原城市群PM_2.5浓度驱动因子联动效应及非线性影响[J].环境科学,2022,43(12):5344-5353.
ZHOU Zhi-heng,ZHOU Ting-gang,QIN Ning.Linkage Effect and Nonlinear Impact of PM_2.5 Concentration Driving Factors in Central Plains Urban Agglomeration[J].Environmental Science,2022,43(12):5344-5353.
[49]张 军,金梓函,王 玥,等.关中平原城市群PM_2.5时空演变格局及其影响因素[J].环境科学,2022,43(12):5333-5343.
ZHANG Jun,JIN Zi-han,WANG Yue,et al.Temporal and Spatial Evolution Pattern of PM_2.5 and Its Influencing Factors in Guanzhong Plain Urban Agglomeration[J].Environmental Science,2022,43(12):5333-5343.

Memo

Memo:

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Common functions

Last Update: 2024-04-10