Fine particles, including PM2.5, impact human health, especially in a megacity such as Jakarta. Meanwhile, precipitation is one of the most efficient mechanisms to reduce atmospheric particulate matter, including PM2.5. This study investigated the changes in PM2.5 concentrations before and after rain events along with the threshold of precipitation and a certain time lag that affects the reduction of PM2.5 concentrations in Jakarta from 2017 to 2019. PM2.5 concentration datasets from two observation sites at Central and South Jakarta were used in this study. The relative effect and scavenging probability of PM2.5 concentrations were calculated to seek further understanding of the effect of rain events on the decrease of PM2.5 concentrations using hourly data. A Non-Linear Distributed Pause Model was used in this study with hourly rainfall data and hourly air temperature that controlled the reduction in PM2.5 concentrations. This study indicates that higher precipitation provides greater influence to the decrease of PM2.5 concentration in both Central Jakarta and South Jakarta. The precipitation threshold for reducing PM2.5 concentrations in Central Jakarta is 5 mm of rainfall with no time lag and a maximum delay of up to 12 hours. The South Jakarta area is 5 mm of rainfall with a time lag of up to 10 hours. In addition, the results suggest an increase in the probability of the concentration of PM2.5 below the standard (SP) with rainfall and a certain time lag that was greater in South Jakarta, which was up to 19% compared to 11% in Central Jakarta

Distributed Non-Linear Lag Model; Particulate Matter; Precipitation; Relative Effect; Wet Deposition

Jephcote C, Chen H. Environmental injustices of children’s exposure to air pollution from road-transport within the model British multicultural city of Leicester: 2000–2009. Science of the Total Environment 2012;414:140–151.

Anderson JO, Thundiyil JG, Stolbach A. Clearing the air: a review of the effects of particulate matter air pollution on human health. Journal of Medical Toxicology 2012;8(2):166–175.

Vodonos A, Awad YA, Schwartz J. The concentration-response between long-term PM2. 5 exposure and mortality; A meta-regression approach. Environmental research 2018;166:677–689.

Khanna I, Khare M, Gargava P, Khan AA. Effect of PM2. 5 chemical constituents on atmospheric visibility impairment. Journal of the Air & Waste Management Association 2018;68(5):430–437.

Wang X, Zhang R, Yu W. The effects of PM2. 5 concentrations and relative humidity on atmospheric visibility in Beijing. Journal of Geophysical Research: Atmospheres 2019;124(4):2235–2259.

Sun X, Zhao T, Liu D, Gong S, Xu J, Ma X. Quantifying the influences of PM2. 5 and relative humidity on change of atmospheric visibility over recent winters in an urban area of East China. Atmosphere 2020;11(5):461.

Pun V, Mungkasa O, Lestari P, Kusuma R, Tang L, Mehta S, et al. Approaches on implementing innovations to achieving faster progress on air quality improvement in DKI Jakarta, Indonesia. Environmental Epidemiology 2019;3:318.

Kirana DC, Bowo PA. Determinant of Car Demand in Java Island. Economics Development Analysis Journal 2019;8(1):1–8.

Tong R, Liu J, Wang W, Fang Y. Health effects of PM2. 5 emissions from on-road vehicles during weekdays and weekends in Beijing, China. Atmospheric Environment 2020;223:117258.

Herizal, Badan Meteorologi Klimatologi dan Geofisika, editor, Pemerintah Terus Meningkatkan Pemantauan dan Upaya Perbaikan Kualitas Udara. Badan Meteorologi Klimatologi dan Geofisika; 2019. https://www.bmkg.go.id/press-release/?p=pemerintah-terus-meningkatkan-pemantauan-dan-upaya-perbaikan-kualitas-udara&tag=press-release〈=ID.

Li L, Qian J, Ou CQ, Zhou YX, Guo C, Guo Y. Spatial and temporal analysis of Air Pollution Index and its timescale-dependent relationship with meteorological factors in Guangzhou, China, 2001–2011. Environmental Pollution 2014;190:75–81.

Westervelt D, Horowitz L, Naik V, Tai A, Fiore A, Mauzerall DL. Quantifying PM2. 5-meteorology sensitivities in a global climate model. Atmospheric Environment 2016;142:43–56.

Nguyen MV, Park GH, Lee BK. Correlation analysis of size-resolved airborne particulate matter with classified meteorological conditions. Meteorology and atmospheric physics 2017;129(1):35–46.

Ikeuchi H, Murakami M, Watanabe S. Scavenging of PM2. 5 by precipitation and the effects of precipitation pattern changes on health risks related to PM2. 5 in Tokyo, Japan. Water Science and Technology 2015;72(8):1319–1326.

Ouyang W, Guo B, Cai G, Li Q, Han S, Liu B, et al. The washing effect of precipitation on particulate matter and the pollution dynamics of rainwater in downtown Beijing. Science of the Total Environment 2015;505:306–314.

Cugerone K, De Michele C, Ghezzi A, Gianelle V. Aerosol removal due to precipitation and wind forcings in Milan urban area. Journal of Hydrology 2018;556:1256–1262.

Muliane U, Lestari P. Pemantauan kualitas udara ambien daerah padat lalu lintas dan komersial DKI Jakarta: analisis konsentrasi PM2, 5 dan black carbon. Jurnal Teknik Lingkungan 2011;17(2):178–188.

Blanco-Becerra LC, Gáfaro-Rojas AI, Rojas-Roa NY. Influence of precipitation scavenging on the PM2. 5/PM10 ratio at the Kennedy locality of Bogotá, Colombia. Revista Facultad de Ingeniería Universidad de Antioquia 2015;76:58–65.

Wang J, Ogawa S. Effects of meteorological conditions on PM2. 5 concentrations in Nagasaki, Japan. International journal of environmental research and public health 2015;12(8):9089–9101.

Loosmore GA, Cederwall RT. Precipitation scavenging of atmospheric aerosols for emergency response applications: testing an updated model with new real-time data. Atmospheric Environment 2004;38(7):993–1003.

Luan T, Guo X, Zhang T, Guo L. Below-cloud aerosol scavenging by different-intensity rains in Beijing city. Journal of Meteorological Research 2019;33(1):126–137.

Chate D, Rao P, Naik M, Momin G, Safai P, Ali K. Scavenging of aerosols and their chemical species by rain. Atmospheric Environment 2003;37(18):2477–2484.

Quérel A, Monier M, Flossmann AI, Lemaitre P, Porcheron E. The importance of new collection efficiency values including the effect of rear capture for the below-cloud scavenging of aerosol particles. Atmospheric research 2014;142:57–66.

Guo LC, Zhang Y, Lin H, Zeng W, Liu T, Xiao J, et al. The washout effects of rainfall on atmospheric particulate pollution in two Chinese cities. Environmental pollution 2016;215:195–202.

Sun Y, Zhao C, Su Y, Ma Z, Li J, Letu H, et al. Distinct impacts of light and heavy precipitation on PM2. 5 mass concentration in Beijing. Earth and Space Science 2019;6(10):1915–1925.

Barmpadimos I, Hueglin C, Keller J, Henne S, Prévôt A. Influence of meteorology on PM10 trends and variability in Switzerland from 1991 to 2008. Atmospheric Chemistry and Physics 2011;11(4):1813.

Gasparrini A. Distributed lag linear and non-linear models in R: the package dlnm. Journal of statistical software 2011;43(8):1.

Humairoh GP, Syafei AD, Santoso M. Identification of Pollutant Sources of PM2, 5 and PM10 in Waru, Sidoarjo, East Java. Jurnal Teknik ITS 2019;8(2):D24–D28.

Ma CJ, Sera K. The chemical nature of individual size-resolved raindrops and their residual particles collected during high atmospheric loading for PM 2.5. Asian Journal of Atmospheric Environment 2017;11(3):176–183.

Seinfeld JH, Pandis SN. Atmospheric chemistry and physics: from air pollution to climate change. John Wiley & Sons; 2016.

Laakso L, Grönholm T, Rannik U, Kosmale M, Fiedler V, Vehkamäki H, et al. Ultrafine particle scavenging coefficients calculated from 6 years field measurements. Atmospheric Environment 2003;37(25):3605–3613.

Rigby E, Marshall J, Hitschfeld W. The development of the size distribution of raindrops during their fall. Journal of Meteorology 1954;11(5):362–372.

González C, Aristizábal B. Acid rain and particulate matter dynamics in a mid-sized Andean city: The effect of rain intensity on ion scavenging. Atmospheric Environment 2012;60:164–171.