Abstract— Padang City is prone to liquefaction phenomena due to earthquakes. These phenomena can cause various damages to structures, infrastructures, and even can also cause deaths. Therefore, as one of the urban populated cities, the information about liquefaction potential is needed. One of them is by providing a liquefaction potential map, which is useful for mitigation and seismic disaster risks strategies. This article aims to provide a digital map of liquefaction potential in Padang City that integrates with Google Maps. The map is based on 40 coordinates in 7 subdistricts in the city with 3 colored markers that represent the levels of potential liquefaction i.e. no liquefaction level, moderate liquefaction level, and severe liquefaction level. The levels are classified based on the analysis of the secondary Cone Penetration Test data by using the calculation of the Factor of Safety and Liquefaction Potential Index with an earthquake assumption of 8 SR. The result shows that the map has ben able to display information about liquefaction potential, where 32.05% coordinates are classified as no liquefaction level with the highest percentage are in Kuranji, 22.5% are classified as moderate liquefaction level with the highest percentage are in Padang Utara, and 45.0% are classified as severe liquefaction level with the highest percentage are in Koto Tangah.

A. Muhammad, K. Goda, N. A. Alexander, W. Kongko, and A. Muhari, “Tsunami evacuation plans for future megathrust earthquakes in Padang , Indonesia , considering stochastic earthquake scenarios,†pp. 2245–2270, 2017.

A. Hakam and E. Suhelmidawati, “Liquefaction Due to September 30 th 2009 Earthquake in Padang,†Procedia Eng., vol. 54, pp. 140–146, 2013.

R. Kusumawardani, U. Nugroho, and N. N. Isnaeni, “Back Analysis Fenomena Likuifaksi Akibat Gempa Padang 2009,†in seminar nasional edusaintek, 2018, pp. 76–83.

Liliwarti, “Informasi Titik-Titik Likuifaksi akibat Gempa Bumi di Kota Padang,†vol. XV, no. April, pp. 17–23, 2018.

A. Tohari, A. Syahbana, N. Satriyo, and E. Soebowo, “Karakteristik likuifaksi tanah pasiran di kota padang berdasarkan metode microtremor,†in Prosiding pemaparan hasil dan penelitian puslit geoteknologi-LIPI, 2013.

A. Hakam and B. Istijono, “Lesson Learnt from padang Earthquake 2009: the liquefaction effects to collaps buildings,†in 1st international conference on disaster mitigation and management for sustainable development and risk reduction, 2016, no. February, pp. 22–24.

Z. Lee, N. Myint, and K. Kyaw, “Development of Soil Distribution and Liquefaction Potential Maps for Downtown Area in Yangon , Myanmar,†vol. 4, no. 3, pp. 689–701, 2018.

W. P. Htet, M. Thant, and D. Arini, “Probability of Liquefaction Hazard Map for Yangon City , Myanmar,†vol. 020027, no. February 2016, 2018.

S. Das, S. Ghosh, and J. R. Kayal, “Liquefaction potential of Agartala City in Northeast India using a GIS platform,†no. 2014, 2018.

A. F. Cabalar, A. Canbolat, N. Akbulut, S. H. Tercan, and H. Isik, “Soil liquefaction potential in Kahramanmaras, Turkey,†Geomatics, Nat. Hazards Risk, vol. 10, no. 1, pp. 1822–1838, 2019.

A. Marto, F. Pakir, U. Tun, H. Onn, and S. N. Jusoh, “Liquefaction Potential of Nusajaya City,†no. January 2015, 2014.

E. Bakar, H. A. Mooduto, and A. Alanda, “Model Sistem Informasi Berbasis Google Map untuk Pemetaan Sekolah,†in National conference of applied sciences, engineering, business and information technolog, 2016, pp. 141–148.

A. Alanda and E. Bakar, “Design of Private Geographycal Information System (GIS) Server for Battlefield Management System,†JOIV Int. J. Informatics Vis., vol. 1, no. 4, p. 23, 2017.