Studies of the impact of land use change on groundwater on the southern slopes of Merapi Volcano tend to be carried out on a macro basis. Micro studies, especially in groundwater transition zones,  have not been previously conducted. In-depth studies need to be undertaken in the groundwater transition zone on the southern slope of Merapi Volcano to identify the impact of land use change on the dynamics of groundwater depth in 2012-2021. Data was collected through field surveys and remote sensing. Groundwater depth data were collected through field surveys in 2012 and 2021. Groundwater depth data were measured in dug wells. The location of the excavated well was determined by using the systematic random sampling method. Groundwater depth data were analyzed using the kriging spatial interpolation method. The results of groundwater depth interpolation in 2012 and 2021 were then compared to determine the changes. Rainfall data were also used in the study. Rainfall data were collected using remote sensing data through cloud computing. Literature studies related to the condition of monitoring wells were also used to determine groundwater dynamics based on rainfall conditions. Data on land use change for 2012-2021 were collected using remote sensing data. Land use change was analyzed using pansharpening, supervised classification, and overlay methods. Cross-tabulation analysis was performed to determine the impact of land use change on groundwater depth. The groundwater depths in the study area were classified into <6 m, 6-11 m, and >11 m. Changes in land use from irrigated rice fields to settlements and open land to scrub occurred predominantly in the study area. Changes in land use did not have a significant impact on changes in groundwater depth in the study area. Based on cross-tabulation analysis, it is known that 11.46% of the study area experienced groundwater deepening, 7.73% experienced groundwater siltation, and 80.81% experienced no change in groundwater depth in the period of 2012-2021. Groundwater deepening generally occurs in areas dominated by scrub and settlements far from river channels. Groundwater that grows shallower and does not change in depth occurs around irrigated rice fields close to river channels. Land use change that does not significantly impact groundwater depth is likely to occur because rainfall in the study area is high. The aquifer material in the study area also had an excellent ability to drain groundwater coming from the upper slopes of Merapi Volcano.

Butt, A., Shabbir, R., Ahmad, S. S., & Aziz, N. (2015). Land use change mapping and analysis using Remote Sensing and GIS: A case study of Simly watershed, Islamabad, Pakistan. Egyptian Journal of Remote Sensing and Space Science, 18(2), 251–259. https://doi.org/10.1016/j.ejrs.2015.07.003

El Garouani, M., Radoine, H., Lahrach, A., & Jarar Oulidi, H. (2023). Spatiotemporal Analysis of Groundwater Resources in the Saïss Aquifer, Morocco. Water (Switzerland), 15(1). https://doi.org/10.3390/w15010105

Fayaz, A., Shafiq, M., Singh, H., & Ahmed, P. (2020). Assessment of spatiotemporal changes in land use / land cover of North Kashmir Himalayas from 1992 to 2018. Modeling Earth Systems and Environment, June, 1–13. https://doi.org/10.1007/s40808-020-00750-9

Funk, C., Peterson, P., Landsfeld, M., Pedreros, D., Verdin, J., Shukla, S., Husak, G., Rowland, J., Harrison, L., Hoell, A., & Michaelsen, J. (2015). The climate hazards infrared precipitation with stations - A new environmental record for monitoring extremes. Scientific Data, 2, 1–21. https://doi.org/10.1038/sdata.2015.66

Gebeyehu, A. E., Chunju, Z., & Yihong, Z. (2019). Assessment and mapping of land use change by remote sensing and GIS: A Case Study of Abaya Chamo Sub-basin, Ethiopia. Nature Environment and Pollution Technology, 18(2), 549–554.

Ghazavi, R., & Ebrahimi, H. (2016). Impacts of land-use change on groundwater resources using remote sensing and numerical modeling. Journal of Biodiversity and Environmental Sciences, 9(4), 149–157.

Hendrayana, H., Harijoko, A., Riyanto, I. A., Nuha, A., & Ruslisan. (2023). Groundwater Chemistry Characterization in The South and Southeast Merapi Volcano, Indonesia. Indonesian Journal of Geography, 55(1), 10–29. https://doi.org/10.22146/ijg.76433

Hendrayana, H., Nuha, A., Riyanto, I. A., & Aprimanto, B. (2021). Kajian Perubahan Muka Airtanah di Cekungan Airtanah Yogyakarta-Sleman. Majalah Geografi Indonesia, 35(1), 30–44. https://doi.org/10.22146/mgi.62396

Hendrayana, H., & Vicente, V. A. de S. (2013). Cadangan Airtanah Berdasarkan Geometri dan Konfigurasi Sistem Akuifer Cekungan Airtanah Yogyakarta-Sleman. Prosiding Seminar Nasional Kebumian Ke-6, 356–370.

Hussin, N. H., Yusoff, I., & Raksmey, M. (2020). Comparison of applications to evaluate groundwater recharge at lower Kelantan river basin, Malaysia. Geosciences (Switzerland), 10(8), 1–25. https://doi.org/10.3390/geosciences10080289

Jain, S., Tiwari, V., Thapa, A., Mangla, R., Jaiswal, R. K., Kumar, V., Tiwari, S., Tulbure, M. G., Galkate, R., Lohani, A. K., & Pandey, K. (2022). Performance Evaluation of Google Earth Engine Based Precipitation Datasets Under Different Climatic Zones over India. Remote Sensing in Earth Systems Sciences, 5(4), 263–276. https://doi.org/10.1007/s41976-022-00077-2

Karimian, K., Amini, A., & Ghaiumi Mohammadi, H. (2019). The Impact of Land Use/Land Cover Changes on Groundwater Resources Using Remote Sensing & GIS (Case Study: Khan-Mirza Plain). Desert, 24(2), 319–330. https://jdesert.ut.ac.ir/article_76388.html

Kumar, P. J. S. (2022). GIS-based mapping of water-level fluctuations (WLF) and its impact on groundwater in an Agrarian District in Tamil Nadu, India. Environment, Development and Sustainability, 24(1), 994–1009. https://doi.org/10.1007/s10668-021-01479-w

Kumar, S., Gupta, S., Sinha, R., Logan, A., Prakash, S., Shekhar, S., Mason, P. J., & Dijk, W. M. Van. (2021). Strongly Heterogeneous Patterns of Groundwater Depletion in Northwestern India. Journal of Hydrology, 598(May), 126492. https://doi.org/10.1016/j.jhydrol.2021.126492

Longley, P. A., Goodchild, M. F., Maguire, D. J., & Rhind, D. W. (2011). Geographic Information Science and Systems. John Wiley and Son Inc.

Manny, L., Atmaja, R. R. S., & Putra, D. P. E. (2016). Groundwater Level Changes in Shallow Aquifer of Yogyakarta City , Indonesia : Distribution and Causes. Journal of Applied Geology, 1(2), 89–99.

Masoud, A. A., Koike, K., Mashaly, H. A., & Gergis, F. (2016). Spatio-temporal trends and change factors of groundwater quality in an arid area with peat rich aquifers : Emergence of water environmental problems in Tanta District , Egypt. Journal of Arid Environments, 124, 360–376. https://doi.org/10.1016/j.jaridenv.2015.08.018

Mishra, N., Khare, D., Gupta, K. K., & Shukla, R. (2014). Impact of land use change on groundwater ‐ a review. Advances in Water Resource Dan Protection, 2(2), 28–41.

Neritarani, R., & Sejati, S. P. (2021). The Impact of Rapid Urban Growth on Potential Groundwater Pollution in Ngemplak Sub-District, Sleman District. Jurnal Wilayah Dan Lingkungan, 9(2), 198–212. https://ejournal2.undip.ac.id/index.php/jwl/article/view/10140

Nofrita, S., & Krol, B. G. C. M. B. (2014). The Livelihood Analysis in Merapi Prone Area After 2010 Eruption. Indonesian Journal of Geography, 46(2), 195. https://doi.org/10.22146/ijg.5790

Ochuko, D., & Lecturer, S. (2015). Change Detection in Landuse / Landcover Mapping in Asaba, Niger Delta B/W 1996 and 2015. a Remote Sensing and Gis Approach. British Journal of Environmental Sciences, 3(3), 42–61.

Oiro, S., Comte, J., Soulsby, C., Macdonald, A., & Mwakamba, C. (2020). Depletion of Groundwater Resources Under Rapid Urbanisation in Africa : Recent and Future Trends in the Nairobi Aquifer System , Kenya. Hydrogeology Journal, 2020(28), 2635–2656. https://doi.org/10.1007/s10040-020-02236-5

Purawantara, S., Suprayogi, S., Hadi, M. P., & Purnama, I. L. S. (2019). The Impact of Land Use Change on Water Resources in The Southern Foot Plain of Merapi. Southeast Asian Geography Association (SEAGA) 13 Th Conference. https://doi.org/10.1088/1755-1315/338/1/012031

Purwantara, S., Suprayogi, S., Pramono Hadi, M., & Setyawan Purnama, I. L. (2019). The Impact of Land Use Change on Water Resources in the Southern Foot Plain of Merapi. IOP Conference Series: Earth and Environmental Science, 338(1), 0–8. https://doi.org/10.1088/1755-1315/338/1/012031

Razi, M. H., Wilopo, W., & Eka Putra, D. P. (2023). Spatiotemporal analysis of groundwater level trends and recharge rate estimation in the unconfined aquifer of Yogyakarta-Sleman Groundwater Basin, Indonesia. Journal of Degraded and Mining Lands Management, 11(1), 4887–4897. https://doi.org/10.15243/jdmlm.2023.111.4887

Riasasi, W., & Sejati, S. P. (2019). Potential of Groundwater to Supply Domestic Water Necessity in Evacuation Shelters of Merapi Volcano Eruption. IOP Conference Series: Earth and Environmental Science, 1–11. https://doi.org/10.1088/1755-1315/271/1/012014

Sajjad, M. M., Wang, J., Abbas, H., Ullah, I., Khan, R., & Ali, F. (2022). Impact of Climate and Land-Use Change on Groundwater Resources, Study of Faisalabad District, Pakistan. Atmosphere, 13(7), 1–15. https://doi.org/10.3390/atmos13071097

Sejati, S. P. (2019). Perbandingan Akurasi Metode IDW dan Kriging dalam Pemetaan Muka Air Tanah. Majalah Geografi Indonesia, 33(2), 49–57. https://doi.org/10.22146/mgi.41473

Sejati, S. P. (2020). Potensi pencemaran air tanah bebas pada sebagian kawasan resapan air di Lereng Selatan Gunung Api Merapi. Jurnal Pendidikan Geografi: Kajian, Teori, Dan Praktik Dalam Pendidikan Dan Ilmu Geografi, 25(01), 25–38. https://doi.org/http://dx.doi.org/10.17977/um017v25i12020p025

Sejati, S. P. (2021). Tingkat Fluktuasi Air Tanah pada Jangka Pendek di Kecamatan Ngemplak, Kabupaten Sleman, Provinsi Daerah Istimewa Yogyakarta. Jurnal Teknologi Lingkungan, 22(1), 121–129. https://doi.org/10.29122/jtl.v22i1.3985

Sejati, S. P., & Adji, T. N. (2013). Kajian potensi air tanah di lereng selatan Gunung Api Merapi untuk mencukupi kebutuhan domestik pada hunian sementara. Universitas Gadjah Mada.

Sejati, S. P., & Prayoga, R. E. (2023). Analysis on unconfined groundwater availability during dry and rainy season using dynamic approach in Ngemplak, Sleman, Yogyakarta, Indonesia. Jurnal Pendidikan Geografi: Kajian,Teori, Praktik Dalam Bidang Pendidikan Dan Ilmu Geografi, 28(1), 38–51. https://doi.org/10.17977/um017v28i12023p38-51

Seyedmohammadi, J., Esmaeelnejad, L., & Shabanpour, M. (2016). Spatial Variation Modeling of Groundwater Electrical Conductivity Using Geostatistics and GIS. Modeling Earth Systems and Environment, 2(4), 1–10. https://doi.org/10.1007/s40808-016-0226-3

Siddik, M. S., Tulip, S. S., Rahman, A., Islam, M. N., Haghighi, A. T., & Mustafa, S. M. T. (2022). The impact of land use and land cover change on groundwater recharge in northwestern Bangladesh. Journal of Environmental Management, 315(April), 1–19. https://doi.org/10.1016/j.jenvman.2022.115130

Steward, D. R., & Allen, A. J. (2016). Peak Groundwater Depletion in the High Plains Aquifer, Projections from 1930 to 2110. Agricultural Water Management, 17, 36–48.

Wang, Y., Victor, O., & Zhao, T. (2017). Interpolation of spatially varying but sparsely measured geo-data : A comparative study. Engineering Geology, 231(October), 200–217. https://doi.org/10.1016/j.enggeo.2017.10.019

Widodo, D. R. (2015). Penggunaan Sistem Informasi Geografi untuk Mengetahui Perubahan Penggunaan Lahan Permukiman dan Dampak Letusan Gunung Merapi di Kecamatan Cangkringan. 135–139.

Wilopo, W., Putra, D. E. P., & Hendrayana, H. (2021). Impacts of precipitation , land use change and urban wastewater on groundwater level fluctuation in the Yogyakarta-Sleman Groundwater Basin , Indonesia. Environmental Monitoring and Assessment, 193(76), 1–14. https://doi.org/10.1007/s10661-021-08863-z