The development of housing in Yogyakarta eventually led to increased levels of runoff. To mitigate runoff increases, infiltration wells were constructed in a specific network. The northern part of Yogyakarta is now facing urbanization, and there are many housing blocks that are being constructed complete with the runoff drainage system. This study aims to reveal the role of the infiltration wells network about runoff and its effectiveness concerning the sediment load in the urban area. The drainage networks in the research area function as a watershed, but not with a single outlet. The runoff flow was spreading through the drainage system and did not accumulate on the single outlet. It can be seen that some infiltration wells supposed as a well, which is a place of accumulation of runoff and sediment.  Most of the infiltration wells have been filled with sediment up to over a quarter, or even more than half, of their carrying volume. Granulometry measurement shows that the percentage of clay, loam, sand, and gravel in each well tend to differ for every sample. The differences between filled wells and their sediment grain depend on the location of those wells. Maintenance of the wells is required, such as sediment dredging, to rejuvenate them and improve their efficiency.

Arafat, Y., (2008). Reduksi beban aliran drainase permukaan menggunakan sumur resapan. Jurnal SMARTek, 6(3), 144-153.

Charters, F.J., Cochrane, T.A., & O’Sullivan, A.D., (2015). Particle size distribution variance in untreated urban runoff and implication on treatment selection. Water Research, 85, 337-345.

Giyarsih, S.R., (2010). Pola spasial transformasi wilayah di koridor Yogyakarta-Surakarta. Forum Geografi, 24(1), 28-38.

Indramaya, E.A., & Purnama, I.L.S., (2013). Rancangan sumur resapan air hujan sebagai salah satu usaha konservasi air tanah di perumahan dayu baru kabupaten sleman daerah istimewa Yogyakarta. Jurnal Bumi Indonesia, 2(3).

Jang, J.H., Chang, T.H., & Chen, W.B., (2018). Effect of inlet modelling on surface drainage in coupled urban flood simulation. Journal of Hydrology, 562, 168-180.

Jousset, P., Pallister, J., Surono, (2013). The 2010 eruption of Merapi volcano. Journal of Volcanology and Geothermal Research, 261, 1-6.

Kellner, E., & Hubbart, J.A., (2018). Spatiotemporal variability of suspended sediments particle size in a mixed-land use watershed. Science of the Total Environment, 615, 1164-1175.

Kusumastuti, D.I., Jokowinarno, D., Khotimah, S.N., Dewi, C., & Yuniarti, F., (2014). Infiltration well to reduce the impact of land use changes on flood peaks: A case study of Way Kuala Garuntang catchment, Bandar Lampung, Indonesia. Hydrology and Earth System Sciences, 11, 5487-5513.

Lacotelli, L., Mark, O., Mikkelsen, S., Arnbjerg-Nielsen, K., Deletic, A., Roldin, M., & Binning, P.J., (2017). Hydrologic impact of urbanization with extensive stormwater infiltration. Journal of Hydrology, 544, 524-537.

Lassabatere, L. Angulo-Jaramillo, R., Goutland, D., Latellier, L., Gaudet, J.P., Winiarski, T., & Delolme, C. (2010). Effect of the settlement of sediment on water infiltration in two urban infiltration basins. Geoderma, 156, 316-325.

undoubtedly, P.N., Wang, K., Tang, Q., Nzeukou, A.N., Billong, N., Melo, U.C., & Xue-min, C., (2018). Review on the uses of volcanic ash for engineering applications. Resources, Conservation & Recycling, 137, 177-190.

Li, C., Liu, M., Hu, Y., Shi, T., Qu, X., & Walter, M.T., (2018). Effects of urbanization on direct runoff characteristics in urban functional zones. Science of the Total Environment, 643, 301-311.

Li, L., Shan, B., & Yin, C., (2012). Stormwater runoff pollution loads from an urban catchment with rainy climate in China. Frontiers of Environmental Science & Engineering, 6(5), 672-677.

Li, X.Y., Contreras, S., Sole-Benet, A., Canton, Y., Domingo, F., Lazaro, R., Lin, H., Wesemael, B.V., & Puigdefabregas, J., (2011). Controls of infiltration-runoff processes in Mediterranean karst rangelands in SE Spain. Catena, 86, 98-109.

Maeno, F., Nakada, S., Yoshimoto, M., Shimano, T., Hokanishi, N., Zaennudin, A., & Iguchi, M., (2019). A sequence of a Plinian eruption preceded by dome destruction at Kelud volcano, Indonesia, on February 13, 2014, revealed from tephra fallout and pyroclastic density current deposits. Journal of Volcanology and Geothermal Research, Volume 382, Pages 24-41

Meyer, J.L., Paul, M.J., & Taulbee, W.K., (2005). Stream ecosystem function in urbanizing landscapes. Journal of the North American Benthological Society, 24, 602-612.

ODOT, (2014). Hydraulics Manual. Appendix F – Rational Method. Oregon: Oregon Department of Transportation.

Rahardjo, W., (1995). Peta Geologi Lembar Yogyakarta, Skala 1:100.000. Bandung: Badan Geologi.

Russel, K.L., Vietz, G.D., & Fletcher, T.D., (2018). Urban catchment runoff increases bedload sediment yield and particle size in stream channels. Anthropocene, 23, 53-66.

Sudarmadji, (1997a). Dampak hidrologis perubahan penggunaan lahan di kawasan utara Yogyakarta. (In Bahasa). Jurnal Manusia dan Lingkungan, 12, Th.IV.1997. ISSN: 0854-5510.

Sudarmadji, (1997b). Perubahan kualitas air dari hujan menjadi limpasan di daerah sub-urban padat perumahan, sinduharjo, sleman, Yogyakarta. (In Bahasa). Majalah Geografi Indonesia, 19, Th.11 Maret 1997. ISSN: 0125-1790.

Suprayogi, S., (2015). Pengembangan ekodrainase untuk pencegahan banjir perkotaan di Yogyakarta. Laporan Penelitian. Fakultas Geografi, UGM.

Sunjoto, (1994). Infiltration wells and urban drainage concept. International Association of Hydrological Sciences Publications, 222, 527-532.

Suzuki, Y.J., , Iguchi, M., (2017). Determination of the mass eruption rate for the 2014 Mount Kelud eruption using three-dimensional numerical simulations of volcanic plumes. Journal of Volcanology and Geothermal Research, . Volume 382, Pages 42-49

Zhu, H., Yu, M., Zhu J., Lu, H., Lao, R., (2018). Simulation study on effect of permeable pavement on reducing flood risk of urban runoff. International Journal of Transportation Science and Technology, in press, https://doi.org/10.1016/j.ijtst.2018.12.001