The excavated slope of the diversion tunnel outlet at the Leuwikeris Dam was designed based on core test data and the Circular Failure Chart (CFC) method. Stability of the excavated slope under static and seismic loads has not been verified using a different method. The objective of this research was to evaluate performance of the excavated slope under static and seismic loads using the finite element method (FEM).  Stability analyses of the natural slope were also carried out to assess the improved stability of the slope after excavation. Geological mapping, examinations of drill cores and borehole logs, and laboratory tests were conducted to characterise the soils and rocks comprising the tunnel outlet slope. The rock masses were characterised using the Geological Strength Index (GSI) for the input parameters of the Generalised Hoek-Brown criterion. The slope stability analyses under static and seismic loads were performed using the finite element-based computer package RS2. The results show that the diversion tunnel construction site consists of residual soil and very poor to fair quality andesite breccia rock and tuff breccia with thin claystone intercalation. The groundwater table was located approximately 40 m below the ground surface. In general, the seismic load reduced stability of the slopes. The critical strength reduction factor (SRF) values of the natural portal slope, which had 40º inclination, were 3.6 and 1.45 under static and seimic loads, respectively. Meanwhile, the SRF values of the excavated slope, which had seven benches and 55 to 74º inclinations, were 3.83 and 1.78 under static and seismic loads, respectively. The natural and excavated slopes were considered stable under static and seismic loads and met the stability criteria specified by the National Standardization Agency (2017). The slope design increased the slope FS values by 6% and 20% under static and seismic loads, respectively.

finite element; Leuwikeris Dam; seismic load; slope stability; tunnel outlet

ASTM International (1998). ASTM D3080-98: Standard Test Method for Direct Shear Test of Soils Under Consolidated Drained Conditions. West Conshohocken, PA.

ASTM International (2009). ASTM D7263-09: Standard Test Methods for Laboratory Determination of Density (Unit Weight) of Soil Specimens. West Conshohocken, PA.

Bieniawski, Z. T. (1989). Engineering Rock Mass Classification Mining and Mineral Resources Research Institute. Pennsylvania State University.

Budhitrisna, T. (1986). Geological Map of Tasikmalaya Sheet, West Java. Geological Research and Development Centre. Bandung. Deere, D.U. 1963. Technical description of rock cores for engineering purposes. Felsmechanik und Ingenieur geologie 1, pp. 16–22.

Hoek, E., & Bray, J. W. (1981). Rock slope engineering. 3rd ed. Institute of Mining and Metallurgy, London.

Hoek, E., Carranza-Torres, C., & Corkum, B. (2002). Hoek-Brown criterion – 2002 edition. In: Hammah R, Bawden W, Curran J, Telesnicki M, editors. Mining and tunneling innovation and opportunity, proceedings of the 5th North American rock mechanics symposium and 17^th tunneling Association of Canada conference. Toronto, Canada. Toronto: University of Toronto.

Hoek E., Carter T. G., & Diederichs M. S. (2013). Quantification of the Geological Strength Index Chart. US Rock Mechanics/Geomechanics Symposium), San Fransisco.

ISRM (1981). The Complete ISRM Suggested Methods for Rock Characterization, Testing, Monitoring, Ankara, ISRM Turkish National Group.

Jaramillo, C. A. (2017). Impact of seismic design on tunnels in rock – Case histories. Underground Space 2, pp. 106–114.

Murti, A. B. (2019). Engineering geological charac teristics of diversion tunnel at Leuwikeris Dam, Ciamis, West Java. Unpublished undergraduate thesis. Department of Geological Engineering, Universitas Gadjah Mada. Indonesia.

National Center for Earthquake Studies. (2017). Indonesian seismic sources and seismic hazard maps 2017—Center for Research and Develop ment of Housing and Resettlement, Ministry of Public Works and Housing, Indonesia.

National Standardization Agency of Indonesia. (2017). SNI 8460:2017: Geotechnical design requirements. Jakarta. Indonesia.

PT Hutama Karya (Persero) (2018). Report on the 2D pole-dipole electrical resistivity survey to support rock investigation. Bandung. Indonesia.

Shivakugan, N., Shukla, S. K., & Das, B. (2013). Rock Mechanic An Introduction. New York: CRC Press.

Sunardi (2019). Evaluation of engineering geological conditions and stability analysis of diversion tunnel excavation at Leukeris Dam, Ciamis, West Java. Unpublished Master of Engineering Thesis. Department of Geological Engineering, Faculty of Engineering, Universitas Gadjah Mada. Indonesia.