Simulasi Penyebaran dan Persentase Fatalitas Oleh Gas SO2 dan CO2 Hasil Pembakaran PLTU Independent Power Producer (IPP) Lombok Timur (50 MW) Dengan Low Rank Coal Menggunakan Model Gaussian

Amrullah, Shafwan; Rohman, Sopyan Ali; Rizaldi, Lalu Heri

doi:10.35970/jppl.v4i1.1193

Cited by 1 publication

(1 citation statement)

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“…With such high electricity demand, the requirement for coal as fuel at the power plant has also surged. However, coal combustion stands as the primary contributor to toxic gases in the atmosphere, including CO [11], while PM 2.5 and PM 10 are the byproduct of this fossil fuel combustion [12]. Numerous endeavors have been undertaken to curtail exhaust gas emissions from the power plant, including the utilization of co-firing technology with sawdust [13] and the implementation of soot blowers at the Pelabuhan Ratu Power Plant [14].…”

Section: Introductionmentioning

confidence: 99%

Spatial and temporal distribution model of carbon monoxide (CO) and particulate matter (PM) emission around PLTU Pelabuhan Ratu, Sukabumi, West Java

Shofy,

Manessa,

Wibowo

2024

Eighth Geoinformation Science Symposium 2023: Geoinformation Science for Sustainable Planet

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The rising demand for electricity, driven primarily by coal-fired power plants, has escalated concerns over hazardous gas emissions and their impact on air quality and human health. This study focuses on the Pelabuhan Ratu region, where there is a notable gap in understanding the spatial and temporal distribution of particulate matter (PM) and carbon monoxide (CO). To address this, we conducted a ground survey to measure concentrations of CO, PM2.5, and PM10 at various points. Additionally, we utilized Landsat 8 satellite imagery to predict the spatial distribution of these aerosols, while also developing a one-year temporal model. Pelabuhan Ratu's unique geomorphology, encompassing both mountains and coasts, significantly influences pollutant concentrations, which vary with elevation and proximity to the power plant. Employing the Random Forest machine learning algorithm, we predicted concentrations of CO, PM2.5, and PM10 by integrating ground-level gas concentrations with satellite-derived vegetation indices, ambient temperature, altitude, land use, wind direction, and humidity data. Our findings reveal varied predictive accuracies: the CO model exhibited a low correlation value (0.32) and a Root Mean Square Error (RMSE) of 136 ppm, suggesting a less reliable prediction. In contrast, the PM2.5 model showed a moderate correlation (0.474) with an RMSE of 18.4 µg/m³. The PM10 model performed slightly better, achieving a correlation of 0.56 and an RMSE of 55.4 µg/m³. These results underscore the challenges and potential of using integrated ground and satellite data for predicting air pollutant concentrations in complex geographic settings.

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Section: Introductionmentioning

confidence: 99%