Water Quality Analysis Using NDTI and TSS Parameters Based on Sentinel Image Data in Jakarta Bay Waters
Article Sidebar
Main Article Content
Abstract
This study investigates the spatial variability of water quality in Jakarta Bay using remote sensing techniques, focusing on turbidity and sediment levels. The research employs Sentinel-2A satellite imagery processed through Google Earth Engine (GEE) and utilizes two key parameters: the Normalized Difference Turbidity Index (NDTI) and Total Suspended Solids (TSS). Jakarta Bay, a shallow marine area in northern Jakarta, is significantly affected by urban runoff, industrial waste, and other anthropogenic pressures. Five observation points were selected to represent different environmental conditions and levels of human influence. The analysis revealed distinct variations in water quality. Point 1 exhibited the highest turbidity (NDTI = 0.21) and TSS (46.81 mg/L), indicating a heavy presence of suspended particles likely due to upstream discharge and shoreline activity. Point 5 showed the lowest turbidity and TSS values, suggesting clearer water and minimal pollutant input. Interestingly, point 3 had the highest turbidity (NDTI = 0.23) but the lowest TSS (23.49 mg/L), reflecting the presence of fine particles that increase light scattering but contribute less to sediment mass. The use of satellite-based indicators proved effective in identifying spatial differences in water quality across Jakarta Bay. This approach offers a cost-efficient, large-scale monitoring method that supports environmental assessment and planning. The results underscore the impact of local factors on water conditions and demonstrate the importance of combining turbidity and sediment metrics. Ultimately, this study provides valuable insights to guide targeted water management strategies and contributes to achieving Sustainable Development Goal 6: ensuring clean water and sanitation for all.
Downloads
Article Details
This work is licensed under a Creative Commons Attribution 4.0 International License.
Accepted 2025-06-24
Published 2025-06-30
References
[1] Bid, S. and Siddique, M.A., 2019. Assessment of water turbidity using remote sensing techniques: A review. Environmental Monitoring and Assessment, 191(5), pp.1–12.
[2] Environmental Protection Agency (EPA), 2023. Turbidity in Water. [online] Available at: https://www.epa.gov/turbidity [Accessed 20 Apr. 2025].
[3] Fajar, E., 2022. Total suspended solids (TSS) analysis and monitoring in water quality management. International Journal of Environmental Research and Public Health, 19(15), pp.1–9.
[4] Jiyah, A., Hidayat, S. and Wulandari, S., 2017. Impact of high total suspended solids (TSS) levels on aquatic life. Aquatic Biology, 40(2), pp.79–86.
[5] Kahle, A.B. and Gitelson, A.A., 2003. Remote sensing of water turbidity in Lake Michigan using MODIS and SeaWiFS data. Journal of Environmental Quality, 32(4), pp.1557–1565.
[6] Nurmalasari, L., Widodo, C.E. and Nugroho, T., 2018. Pemanfaatan citra Sentinel-2A untuk pemetaan tutupan lahan dan analisis perubahan penggunaan lahan. Jurnal Penginderaan Jauh dan Pengolahan Citra Digital, 15(1), pp.21–30.
[7] Putri, R.N., Hidayat, R. and Sari, R.M., 2021. Utilization of Sentinel-2A imagery for environmental monitoring and land use planning. Jurnal Sains dan Teknologi Lingkungan, 13(2), pp.87–95.
[8] Rachmansyah, S., Arief, M. and Purwanto, D., 2014. Evaluation of turbidity as an indicator for water quality monitoring in Indonesian rivers. Journal of Water Quality, 39(1), pp.45–52.
[9] Sinaga, E., Tanjung, D. and Utami, R., 2024. The distribution of suspended solids in coastal areas: A case study of Jakarta Bay. Marine Environmental Research, 72(4), pp.112–121.
[10] Star, K., Cukier, S. and Kurniawan, T., 2013. Total Suspended Solids (TSS) in water: Impact on water quality and aquatic ecosystems. Journal of Environmental Science and Technology, 11(4), pp.350–360.
[11] Tso, C., Zhang, Z., Li, D. and Li, Z., 2014. Application of satellite-based Normalized Difference Turbidity Index for coastal water quality monitoring: A case study of Chesapeake Bay. Journal of Coastal Research, 30(4), pp.753–764.
[12] Zhao, J., Yao, S., Zhang, X. and Yuan, X., 2011. Estimation of total suspended solids (TSS) using MODIS data: Application in the Yangtze River Estuary. Environmental Monitoring and Assessment, 175, pp.441–452