This study discusses the assessment of liquefaction by triaxial consolidated undrained (CU) testing. The soil sample employs Rembang silica sand with a grain size distribution that lies within the zone of liquefaction. In the test, Liquefaction develops in sand when the ratio of the change in pore water pressure to its confining stress (Ru) turns approximately 1 and the deviator stress drops to approximately zero. According to the findings, loose to medium-dense sand experience liquefaction when the applied confining stress is low (<100 kPa). In sandy soils, limited liquefaction occurs at confining pressures of 200 − 400 kPa with the range of relative densities around 34.41% − 47.78%. Critical state line develops from Triaxial CU testing to predict the undrained and drained behavior of sand.

Bardet, J.P., & Kapuskar, M., 1993, Liquefaction Sand Boils in San Francisco during 1989 loma prieta earthquake. Journal of Geotechnical Engineering, 119(3), 543–562.

Bradley, K., Mallick, R., Andikagumi, H., Hubbard, J., Meilianda, E., Switzer, A., Du, N., Brocard, G., Alfian, D., Benazir, B., Feng, G., Yun, S.H., Majewski, J., Wei, S., & Hill, E.M., 2019, Earthquake-triggered 2018 Palu Valley landslides enabled by wet rice cultivation. Nature Geoscience, 12, 935–939.

Castro, G., 1969, Liquefaction of sands [Ph.D. thesis]. Harvard University.

Cubrinovski, M., Henderson, D., & Bradley, B., 2012, Liquefaction Impacts in Residential Areas in the 2010-2011 Christchurch Earthquakes. One Year after the 2011 Great East Earthquake, 811–824.

da Fonseca, A.V., Cordeiro, D., & Molina-Gómez, F., 2021, Recommended Procedures to Assess Critical State Locus from Triaxial Tests in Cohesionless Remoulded Samples. Geotechnics, 1(1), 95–127.

Idriss, I.M., & Boulanger, R.W., 2008, Soil Liquefaction during Earthquakes. EERI.

Ishihara, K., 1985, Stability of natural deposits during earthquakes. Proceedings of the 11th International Conference on Soil Mechanics and Foundation Engineering, 321–376.

Ishihara, K., & Koga, Y., 1981, Case studies of liquefaction in the 1964 Niigata earthquake. Soils and Foundations, 21(3), 35–52.

Kiyota, T., Furuichi, H., Hidayat, R. F., Tada, N., & Nawir, H., 2020, Overview of long-distance flow-slide caused by the 2018 Sulawesi earthquake, Indonesia. Soils and Foundations, 60(3), 722–735.

Kramer, S.L., 1996, Geotechnical Earthquake Engineering. Prentice Hall.

Kusumawardani, R., Muhsiung, C., Upomo, T., Huang, R.C., Fansuri, M., & Prayitno, G., 2021, Understanding of Petobo liquefaction flowslide by 2018.09.28 Palu-Donggala Indonesia earthquake based on site reconnaissance. Landslides, 18(9), Article 9.

Kusumawardani, R., Upomo, T., Nugroho, U., & Cahyo, H., 2023, Evaluasi Likuifaksi Pasir Silika Rembang Melalui Uji Triaksial Consolidated Undrained. Jurnal Teknik Sipil, 17(3), 147–152.

Lee, K.L., Seed, H.B., & Makdisi, F.I., 1975, Properties of soil in the San Fernando Hyraulic Fill Dams. Journal of the Geotechnical Engineering Division, ASCE, 101(GT8), Article GT8.

Lestari, A.S., Hartadi, M.D., & Kesumah, A., 2014, Liquefaction potensial evaluation based on critical state parameter concept and piezocone test of sandy sediments Padang Indonesia. Engineering Innovation for Sustainable Development, 133–137.

Mason, H.B., Montgomery, J., Gallant, A.P., Hutabarat, D., Reed, A. N., Wartman, J., Irsyam, M., Simatupang, P.T., Alatas, I.M., Prakoso, W.A., Djarwadi, D., Hanifa, R., Rahardjo, P., Faizal, L., Harnanto, D.S., Kawanda, A., Himawan, A., & Yasin, W., 2021, East Palu Valley flowslides induced by the 2018 M 7.5 Palu-Donggala earthquake. Geomorphology, 373, 107482.

Mitchell, J.K., & Soga, K., 2005, Fundamentals of Soil Behavior. John Wiley & Sons, Inc.

Pamumpuni, A., Sapiie, B., Marshal, M. E., Apriansyah, D., & Anisprawoto, A., 2018, Penyelidikan geologi paska gempa Lombok 5 Agustus 2018. In Kajian rangkaian gempa Lombok Provinsi Nusa Tenggara Barat (pp. 27–34). Pusat Penelitian dan Pengembangan Perumahan dan Permukiman.

Sarah, D., & Soebowo, E., 2013, Liquefaction due to the 2006 Yogyakarta Earthquake: Field Occurrence and Geotechnical Analysis. Procedia Earth and Planetary Science, 6, 383–389.

Seed, H.B., Lee, K.L., Idriss, I.M., & Makdisi, F.I, 1973, Analysis of the slides in the San Fernando Dams during the earthquake of Feb. 9, 1971 (EERC 73-2; Issue EERC 73-2). Earthquake Engineering Research Center.

Seed, H.B., Lee, K.L., Idriss, I.M., & Makdisi, F.I., 1975, The Slides in the San Fernando Dams during the Earthquake of February 9, 1971. Journal of the Geotechnical Engineering Division, ASCE, 101(7), Article 7.

Taylor, M.L., Cubrinovski, M., & Bradley, B.A., 2012, Characterisation of ground conditions in the Christchurch Central Business district. Australian Geomechanics Journal, 42(4), 43–57.

Tsuchida, H., 1970, Prediction and Countermeasure against Liquefaction in Sand Deposits. 3.1-3.33.

Upomo, T., Chang, M., Kusumawardani, R., Prayitno, G., Kuo, C.P., & Nugroho, U., 2023, Assessment of Petobo Flowslide Induced by Soil Liquefaction during 2018 Palu–Donggala Indonesian Earthquake. Sustainability, 15(6), 1–26.

Yamamuro, J.A., & Lade, P.V., 1997, Static liquefaction of very loose sands. Canadian Geotechnical Journal, 34(6), 905–917.

Youd, T.L., 2014, Ground failure investigations following the 1964 Alaska earthquake. Proceedings of the 10 Th National Conference in Earthquake Engineering. Tenth U.S. National Conference on Earthquake Engineering, Anchorage, Alaska.