A Preliminary Result Of Air Quality Identification And Analysis Of Pm10 And Pm2.5 In Steel Industrial Area, Cilegon, Banten

Ira Setiawati; Rahyani Ermawati; Kitai Kang; Insoo Chang; Kihwan Hong; Ervina Ervina; Auliyah Ariani; Ilham Fauzi; Indra Lukman Syah; Fita Sefriana; Yessy Komala Sari

doi:10.21771/jrtppi.2019.v10.no1.p22-28

Authors

Ira Setiawati Center for Chemical and Packaging
Rahyani Ermawati Center for Chemical and Packaging
Kitai Kang Aerosol Research and Technology Plus, Korea
Insoo Chang Aerosol Research and Technology Plus, Korea
Kihwan Hong Aerosol Research and Technology Plus, Korea
Ervina Ervina Aerosol Research and Technology Plus, Korea
Auliyah Ariani Center for Chemical and Packaging
Ilham Fauzi Center for Chemical and Packaging
Indra Lukman Syah Center for Chemical and Packaging
Fita Sefriana Center for Chemical and Packaging
Yessy Komala Sari Center for Chemical and Packaging

DOI:

https://doi.org/10.21771/jrtppi.2019.v10.no1.p22-28

Keywords:

air quality, particulate matter, steel industry, low volume sampler (LVS)

Abstract

The increasingly rapid industrial development has produced pollutants in the form of gases and particles polluting the atmosphere. One of them is the steel industry where the majority of the air pollutants produced is particulate matter. Monitoring the air quality of particulate matter needs to be done routinely to identify and control the effects of air pollution somewhere. The purpose of this study is to identify and analyze particulate matter (PM₁₀ and PM_2.5) in the steel industry area in Cilegon, Indonesia. Ambient particulate matter is sampling by low-volume Sequential Particulate Matter (PM) Sampler with flow rate 5-20 L/minute for 24 hours per day in 4 months from September 2018 to January 2019. The results of identification and analysis of PM₁₀ and PM_2.5 in the steel industry area, Cilegon, Indonesia showed concentrations that varied greatly depending on sampling location conditions, with an average concentration range of 89.38 - 141.13 µg/m³ for PM₁₀ and 21.74 - 50.69 µg/m³ for PM_2.5.

References

Alias, M., Z. Hamzah, & Kenn, L.S. 2007. PM10 and total suspended particulates (TSP) measurements in various power stations. The Malaysian Journal of Analytical Sciences, 11(1): 255-261.

Jia, J., Cheng, S., Yao, S., Xu, T., Zhang, T., Ma, Y., Wang, H., & Duan, W. 2018. Emission characteristics and chemical components of size-segregated particulate matter in the iron and steel industry. Atmospheric Environment, 182: 115-127. doi:10.1016/j.atmosenv.2018.03.051.

Jutze, G.A. and Foster, K.E. 1967. Recommended standard method for atmospheric sampling of fine particulate matter by filter media – high-volume sampler. Journal of the Air Pollution Control Association, 17(1): 17-25. doi:10.1080/00022470.1967.10468936.

Kumar, S.S., Muthuselvam, P., Pugalenthi, V., Subramanian, N., Ramkumar, K.M., Suresh, T., Suzuki, T., & Rajaguru, P. Toxicoproteomic analysis of human lung epithelial cells exposed to steel industry ambient particulate matter (PM) reveals possible mechanism of PM related carcinogenesis. Environmental Pollution, 239: 483-492. doi:10.1016/j.envpol.2018.04.049.

Moreno, T., Jones, T.P., & Richards, R.J. 2004. Characterisation of aerosol particulate matter from urban and industrial environments: examples from Cardiff and Port Talbot, South Wales, UK. Science of the Total Environment, 334-335: 337-346. doi:10.1016/j.scitotenv.2004.04.074.

Republik Indonesia. 1999. RI Government Regulation No.41: Pengendalian Pencemaran Udara. Jakarta.

Rohmah, I., Rita, Salim, C., Hindratmo, B., Lestari, R.P., & Nelson, R. 2018. Perbandingan metode sampling kualitas udara: high volume air sampler (HVAS) dan low volume air sampler (LVAS). Ecolab, 12(2): 83-102

Ruhiat, Y., Syafrizal, Hidayat, S., Indrayono, Y., & Akbar, H. 2017. Estimated contaminated area of air pollutant from industrial in Cilegon. Research Journal of Environmental Sciences, 11(3): 108-115. doi:10.3923/rjes.2017.108.115.

Roychowdhury, A., Chattopadhyaya, V., & Shukla, S. 2016. Reinventing air quality monitoring: potential of low cost alternative monitoring methods. New Delhi: Centre for Science and Environment.

Standar Nasional Indonesia (SNI) 7119.15:2016. 2016. Udara ambien – Bagian 15: Cara uji partikel dengan ukuran ≤ 10 µm (PM10) menggunakan peralatan High Volume Air Sampler (HVAS) dengan metode gravimetri. Jakarta: Badan Standardisasi Nasional.

Wahab, S.A., Fadlallah, S., & Al-Rashdi, M. 2018. Evaluation of the impact of ground-level concentrations of SO2, NOx, CO, and PM10 emitted from a steel melting plant on Muscat, Oman. Sustainable Cities and Society, 38: 675-683. doi:10.1016/j.scs.2018.01.048.

Wang, K., Tian, H., Hua, S., Zhu, C., Gao, J., Xue, Y., Hao, J., Wang, Y., & Zhou, J. 2016. A comprehensive emission inventory of multiple air pollutant from iron and steel industry in China: Temporal trends and spatial variation characteristics. Science of the Total Environment, 559: 7-14. doi:10.1016/j.scitotenv.2016.03.125.

World Health Organization. 2018. Ambient (outdoor) air quality and health. https://www.who.int/news-room/fact-sheets/detail/ambient-(outdoor)-air-quality-and-health. (diakses pada 28 Januari 2019)

Yadav, R., Sahu, L.K., Beig, G., Tripathi, N., & Jaaffrey, S.N.A. 2017. Ambient particulate matter and carbon monoxide at an urban site of India: influence of anthropogenic emissions and dust storms. Environmental Pollution, 225: 291-303. doi:10.1016/j.envpol.2017.01.038