|
|
|
| Effects of emission reduction measures on the particle size distribution characteristics of atmospheric particulate matter: Based on the observations before and after the 2022 Beijing Winter Olympic Games |
| ZHAO Gang1,2, ZHANG Ya-bin1, ZHAO Ming-sheng2, HAN Hui-xia2, LI Gang2, YANG Xiao-yang2, ZHAO Yu-xi2, CHU Yang-xi2, CHE Fei2, GAO Jian2, REN Li-hong1,2 |
1. School of Mine Engineering, North China University of Science and Technology, Tangshan 063210, China;
2. Atmospheric Environment Institute, Chinese Research Academy of Environmental Science, Beijing 100012, China |
|
|
|
|
Abstract To investigate the distribution of particle number concentration (PNC) in Beijing during the 2022 Winter Olympic Games (WOG), particle size distributions ranging from 3 to 660nm were measured using a Scanning Mobility Particle Sizer (SMPS) from December 1, 2021 to March 28, 2022. By comparing the PNC with gaseous pollutants and meteorological parameters, the PNC and particle size distribution characteristics on new particle formation (NPF) days and non-NPF days before and after the WOG were analyzed. The results indicate that PNC decreased with the implementation of emission reduction measures. During the WOG period (February 1to February 20, 2022), the mean PNC, surface area concentration, and volume concentration of particulate matter decreased by approximately 4.0%~33.3%, 17.1%~41.1%, and 11.7%~41.2%, respectively, compared to other periods within the observation period. These reductions demonstrate the effects of local emission reduction measures and coordinated regional pollution control efforts during the WOG. On NPF days, the PNC in the accumulation mode during the Winter Olympics decreased by about 15.3%~25.1%, while ultrafine PNC increased from 12078cm-3in pre-WOG to 20600cm-3 in post-WOG, primarily influenced by favorable nucleation conditions such as high concentrations of O3 and gaseous sulfuric acid, high solar radiation intensity, low NO2 concentrations, and condensation sinks. On non-NPF days, the PNC decreased by 4.4%~5.5% during the emission limitation period, which may be due to the reduction of primary emissions. The PNC showed a bimodal distribution, with the main peak particle sizes in the range of 3~25and 60~150nm on NPF and non-NPF days, respectively. On non-NPF days, PNC in the 10~35 and 50~150nm particle sizes during the WOG decreased by 17.4%~29.0% and 12.0%~24.2%, respectively, which were associated with the reduction of traffic emissions. During the morning and evening traffic peaks (07:00~09:00 and 18:00~22:00) on both NPF and non-NPF days, the PNC decreased, and the decrease in ultrafine PNC on non-NPF days was greater during these periods than during other times, indicating that the reduction in traffic emissions effectively reduced atmospheric PNC.
|
|
Received: 28 October 2022
|
|
|
|
|
|
| Cite this article: |
|
ZHAO Gang,ZHANG Ya-bin,ZHAO Ming-sheng等. Effects of emission reduction measures on the particle size distribution characteristics of atmospheric particulate matter: Based on the observations before and after the 2022 Beijing Winter Olympic Games[J]. CHINA ENVIRONMENTAL SCIENCECE, 2023, 43(6): 2744-2754.
|
|
|
|
| URL: |
| http://www.zghjkx.com.cn/EN/ OR http://www.zghjkx.com.cn/EN/Y2023/V43/I6/2744 |
| [1] |
Mccormick R A, Ludwig J H. Climate modification by atmospheric aerosols[J]. Science, 1967,156(3780):1358-1359.
|
| [2] |
Du W, Wang W G, Liu R R, et al. Insights into vertical differences of particle number size distributions in winter in Beijing, China[J]. Science of the Total Environment, 2022,802:149695.
|
| [3] |
Kompalli S K, Nair V S, Jayachandran V, et al. Particle number size distributions and new particle formation events over the northern Indian Ocean during continental outflow[J]. Atmospheric Environment, 2020,238:117719.
|
| [4] |
亓浩雲,王晓琦,程水源.人为排放及气象因素对空气质量影响的定量分析——以疫情期间邢台市为例[J]. 中国环境科学, 2022,42(8):3512-3521. Qi H Y, Wang X Q, Cheng S Y. Quantitative analysis of the impact of anthropogenic emissions and meteorological factors on air quality:Cases during the epidemic in Xingtai City[J]. China Environmental Science, 2022,42(8):3512-3521.
|
| [5] |
Saha P K, Zimmerman N, Malings C, et al. Quantifying high-resolution spatial variations and local source impacts of urban ultrafine particle concentrations[J]. Science of the Total Environment, 2019,655:473-481.
|
| [6] |
Vu T V, Delgado-Saborit J M, Harrison R M. Review:Particle number size distributions from seven major sources and implications for source apportionment studies[J]. Atmospheric Environment, 2015,122:114-132.
|
| [7] |
Guo S, Hu M, Peng J F, et al. Remarkable nucleation and growth of ultrafine particles from vehicular exhaust[J]. Proceedings of the National Academy of Sciences of the United States of America, 2020, 117(7):3427-3432.
|
| [8] |
Yadav S K, Kompalli S K, Gurjar B R, et al. Aerosol number concentrations and new particle formation events over a polluted megacity during the COVID-19lockdown[J]. Atmospheric Environment, 2021,259:118526.
|
| [9] |
Beck L J, Sarnela N, Junninen H, et al. Differing mechanisms of new particle formation at two arctic sites[J]. Geophysical Research Letters, 2021,48(4):e2020GL091334.
|
| [10] |
Jokinen T, Sipila M, Kontkanen J, et al. Ion-induced sulfuric acid-ammonia nucleation drives particle formation in coastal Antarctica[J]. Science Advances, 2018,4(11):eaat9744.
|
| [11] |
Merikanto J, Spracklen D V, Mann G W, et al. Impact of nucleation on global CCN[J]. Atmospheric Chemistry and Physics, 2009,9(21):8601-8616.
|
| [12] |
Lee S H, Gordon H, Yu H, et al. New particle formation in the atmosphere:from molecular clusters to global climate[J]. Journal of Geophysical Research-Atmospheres, 2019,124(13):7098-7146.
|
| [13] |
Chu B W, Zhang S P, Liu J, et al. Significant concurrent decrease in PM2.5 and NO2 concentrations in China during COVID-19epidemic[J]. Journal of Environmental Sciences, 2021,99:346-353.
|
| [14] |
Bao R, Zhang A C. Does lockdown reduce air pollution? Evidence from 44cities in northern China[J]. Science of the Total Environment, 2020,731:139052.
|
| [15] |
Wang W T, Primbs T, Tao S, et al. Atmospheric particulate matter pollution during the 2008 Beijing Olympics[J]. Environmental Science & Technology, 2009,43(14):5314-5320.
|
| [16] |
Wang T, Xie S D. Assessment of traffic-related air pollution in the urban streets before and during the 2008 Beijing Olympic Games traffic control period[J]. Atmospheric Environment, 2009,43(35):5682-5690.
|
| [17] |
Wang M, Zhu T, Zheng J, et al. Use of a mobile laboratory to evaluate changes in on-road air pollutants during the Beijing 2008 Summer Olympics[J]. Atmospheric Chemistry and Physics, 2009,9(21):8247-8263.
|
| [18] |
杜 朋,李德平,刘建国,等.APEC前后北京郊区大气颗粒物变化特征及其潜在源区分析[J]. 环境科学学报, 2018,38(10):3846-3855. Du P, Li D P, Liu J G, et al.. Pollution characteristics and potential source region analysis of atmospheric particulate matter during 2014APEC in Beijing Surburban[J]. Acta Scientiae Circumstantiae, 2018,38(10):3846-3855.
|
| [19] |
赵素平,余 晔,殷代英,等.交通限行对细颗粒物浓度及其谱分布的影响[J]. 高原气象, 2015,34(3):777-785. Wang S P, Yu Y, Yin D Y, et al. Effect of traffic restriction on fine particle concentrations and their size distributions[J]. Plateau Meteorology, 2015,34(3):777-785.
|
| [20] |
Hao N, Valks P, Loyola D, et al. Space-based measurements of air quality during the World Expo 2010 in Shanghai[J]. Environmental Research Letters, 2011,6(4):044004.
|
| [21] |
黄兵役,王申博,和 兵,等.新冠疫情管控措施对郑州市PM2.5浓度、粒径分布、组分和来源的影响[J]. 环境科学, 2022,43(6):2840-2850. Huang B Y, Wang S B, He, B, et al Influence of COVID-19 prevention and control measures on PM2.5 concentration, particle size distribution, chemical composition, and source in Zhengzhou, China[J]. Environmental science, 2022,43(6):2840-2850.
|
| [22] |
Shen X J, Sun J Y, Yu F Q, et al. Enhancement of nanoparticle formation and growth during the COVID-19lockdown period in urban Beijing[J]. Atmospheric Chemistry and Physics, 2021,21(9):7039-7052.
|
| [23] |
Xu J Z, Ge X L, Zhang X H, et al. COVID-19Impact on the concentration and composition of submicron particulate matter in a typical city of northwest China[J]. Geophysical Research Letters, 2020,47(19):e2020GL089035.
|
| [24] |
Liu L, Zhang J, Du R G, et al. Chemistry of atmospheric fine particles during the COVID-19pandemic in a megacity of eastern China[J]. Geophysical Research Letters, 2021,48(2):e2020GL091611.
|
| [25] |
朱媛媛,汪 巍,高愈霄,等.疫情期间"2+26"城市污染减排成效评估[J]. 中国环境科学, 2021,41(2):505-516. Zhu Y Y, Wang W, Gao Y X, et al. Assessment of emission reduction effect in Beijing, Tianjin and surrounding 26cities from January to March in 2020 during the epidemic of COVID-19[J]. China Environmental Science, 2021,41(2):505-516.
|
| [26] |
Mikkonen S, Romakkaniemi S, Smith J N, et al. A statistical proxy for sulphuric acid concentration[J]. Atmospheric Chemistry and Physics, 2011,11(21):11319-11334.
|
| [27] |
M.Kulmala, Dalmaso M, M. MÄkelÄ J, et al. On the formation, growth and composition of nucleation mode particles[J]. Tellus Series B-chemical & Physical Meteorology, 2001,53(4):479-490.
|
| [28] |
Kulmala M, Hämeri K, Aalto P P, et al. Overview of the international project on biogenic aerosol formation in the boreal forest (BIOFOR)[J]. Tellus Series B-chemical & Physical Meteorology, 2003,53(4):324-343.
|
| [29] |
Hameri K, Vakeva M, Aalto P P, et al. Hygroscopic and CCN properties of aerosol particles in boreal forests[J]. Tellus Series B-Chemical and Physical Meteorology, 2001,53(4):359-379.
|
| [30] |
王申博,余 雪,赵庆炎,等.郑州市两次典型大气重污染过程成因分析[J]. 中国环境科学, 2018,38(7):2425-2431. Wang S B, Yu X, Zhao Q Y, et al. Analysis of the formation of two typical atmospheric heavy pollution episodes in Zhengzhou, China[J]. China Environmental Science, 2018,38(7):2425-2431.
|
| [31] |
Huang X, Ding A J, Gao J, et al. Enhanced secondary pollution offset reduction of primary emissions during COVID-19lockdown in China[J]. National Science Review, 2021,8(2):nwaa137.
|
| [32] |
Le T H, Wang Y, Liu L, et al. Unexpected air pollution with marked emission reductions during the COVID-19outbreak in China[J]. Science, 2020,369(6504):702-706.
|
| [33] |
Kulmala M, Petaja T, Nieminen T, et al. Measurement of the nucleation of atmospheric aerosol particles[J]. Nature Protocols, 2012, 7(9):1651-1667.
|
| [34] |
Zimmerman A, Petters M D, Meskhidze N. Observations of new particle formation, modal growth rates, and direct emissions of sub-10nm particles in an urban environment[J]. Atmospheric Environment, 2020,242:117835.
|
| [35] |
John W, Wall S M, Ondo J L, et al. Modes In The Size Distributions Of Atmospheric Inorganic Aerosol[J]. Atmospheric Environment Part a-General Topics, 1990,24(9):2349-2359.
|
| [36] |
Chu B W, Dada L, Liu Y C, et al. Particle growth with photochemical age from new particle formation to haze in the winter of Beijing, China[J]. Science of the Total Environment, 2021,753:142207.
|
| [37] |
Bianchi F, Praplan A P, Sarnela N, et al. Insight into acid-base nucleation experiments by comparison of the chemical composition of positive, negative, and neutral clusters[J]. Environmental Science & Technology, 2014,48(23):13675-13684.
|
| [38] |
Jokinen T, Sipila M, Kontkanen J, et al. Ion-induced sulfuric acid-ammonia nucleation drives particle formation in coastal Antarctica[J]. Science Advances, 2018,4(11):eaat9744.
|
| [39] |
Lu Y Q, Yan C, Fu Y Y, et al. A proxy for atmospheric daytime gaseous sulfuric acid concentration in urban Beijing[J]. Atmospheric Chemistry and Physics, 2019,19(3):1971-1983.
|
| [40] |
Kerminen V M, Chen X M, Vakkari V, et al. Atmospheric new particle formation and growth:review of field observations[J]. Environmental Research Letters, 2018, 13(10):103003.
|
| [41] |
Mahilang M, Deb M K, Pervez S. Biogenic secondary organic aerosols:A review on formation mechanism, analytical challenges and environmental impacts[J]. Chemosphere, 2021,262:127771.
|
| [42] |
Wildt J, Mentel T F, Kiendler-Scharr A, et al. Suppression of new particle formation from monoterpene oxidation by NOx[J]. Atmospheric Chemistry and Physics, 2014,14(6):2789-2804.
|
| [43] |
Yan C, Nie W, Vogel A L, et al. Size-dependent influence of NOx on the growth rates of organic aerosol particles[J]. Science Advances, 2020,6(22):eaay4945.
|
| [44] |
杨 柳,吴 烨,宋少洁,等.不同交通状况下道路边大气颗粒物数浓度粒径分布特征[J]. 环境科学, 2012,33(3):694-700. Yang L, Wu Y, Song S J, et al. Particle number size distribution near a major road with different traffic conditions[J]. Environmental Science, 2012,33(3):694-700.
|
| [45] |
Vratolis S, Gini M I, Bezantakos S, et al. Particle number size distribution statistics at City-Centre Urban Background, urban background, and remote stations in Greece during summer[J]. Atmospheric Environment, 2019,213:711-726.
|
| [46] |
Moreno T, Reche C, Ahn K H, et al. Using miniaturised scanning mobility particle sizers to observe size distribution patterns of quasi-ultrafine aerosols inhaled during city commuting[J]. Environmental Research, 2020,191:109978.
|
| [47] |
Zhang K M, Wexler A S. Evolution of particle number distribution near roadways -Part I:analysis of aerosol dynamics and its implications for engine emission measurement[J]. Atmospheric Environment, 2004,38(38):6643-6653.
|
| [48] |
Rivas I, Beddows D C S, Amato F, et al. Source apportionment of particle number size distribution in urban background and traffic stations in four European cities[J]. Environment International, 2020, 135:105345.
|
| [49] |
Wihersaari H, Pirjola L, Karjalainen P, et al. Particulate emissions of a modern diesel passenger car under laboratory and real-world transient driving conditions[J]. Environmental Pollution, 2020,265:114948.
|
| [50] |
Kompalli S K, Babu S S, Moorthy K K, et al. The formation and growth of ultrafine particles in two contrasting environments:a case study[J]. Annales Geophysicae, 2014,32(7):817-830.
|
| [51] |
Babu S S, Kompalli S K, Moorthy K K. Aerosol number size distributions over a coastal semi urban location:Seasonal changes and ultrafine particle bursts[J]. Science of the Total Environment, 2016, 563:351-365.
|
| [52] |
郑淑睿,孔少飞,严 沁,等.华北南部冬季大气亚微米颗粒物数浓度变化[J]. 中国环境科学, 2019,39(11):4511-4520. ZHENG S R, Kong S F, Yan Q.et al. Number concentration of submicron particles during winter at a suburban site of the south edge of North China[J]. China Environmental Science, 2019,39(11):4511-4520.
|
| [53] |
郑淑睿,孔少飞,严 沁,等.夏收时段农村大气亚微米颗粒物数浓度分布特征[J]. 中国环境科学, 2019,39(2):478-486. ZHENG S R, Kong S F, Yan Q.et al. Number concentration of submicron aerosols at a rural site during summer harvest period[J]. China Environmental Science, 2019,39(2):478-486.
|
| [54] |
Kulmala M. How particles nucleate and grow[J]. Science, 2003, 302(5647):1000-1001.
|
| [55] |
Pushpawela B, Jayaratne R, Morawska L. Differentiating between particle formation and growth events in an urban environment[J]. Atmospheric Chemistry and Physics, 2018,18(15):11171-11183.
|
| [56] |
Kopanakis I, Chatoutsidou S E, Glytsos T, et al. Impact from local sources and variability of fine particle number concentration in a coastal sub-urban site[J]. Atmospheric Research, 2018,213:136-148.
|
| [57] |
Hama S M L, Cordell R L, Monks P S. Quantifying primary and secondary source contributions to ultrafine particles in the UK urban background[J]. Atmospheric Environment, 2017,166:62-78.
|
|
|
|
