Articles in this field : 8
[J.40] Psyrras, N. K., & Sextos, A. G. (2018). Safety of buried steel natural gas pipelines under earthquake-induced ground shaking: A review. Soil Dynamics and Earthquake Engineering, 106, 254–277.
[J.41] de Risi, R., de Luca, F., Kwon, O.-S., & Sextos, A.G. (2018). Scenario-Based Seismic Risk Assessment for Buried Transmission Gas Pipelines at Regional Scale. Journal of Pipeline Systems Engineering and Practice, 9(4).
[J.49] Psyrras, N. K., Kwon, O., Gerasimidis, S., & Sextos, A. G. (2019). Can a buried gas pipeline experience local buckling during earthquake ground shaking? Soil Dynamics and Earthquake Engineering, 116, 511–529.
[J.50] Tsinidis, G., di Sarno, L., Sextos, A., & Furtner, P. (2019). A critical review on the vulnerability assessment of natural gas pipelines subjected to seismic wave propagation. Part 1: Fragility relations and implemented seismic intensity measures. Tunnelling and Underground Space Technology, 86, 279–296.
[J.53] Tsinidis, G., di Sarno, L., Sextos, A., & Furtner, P. (2019). A critical review on the vulnerability assessment of natural gas pipelines subjected to seismic wave propagation. Part 2: Pipe analysis aspects. Tunnelling and Underground Space Technology, 92, 103056.
[J.58] Psyrras, N., Sextos, A. G., Crewe, A., Dietz, M., & Mylonakis, G. (2020). Physical Modeling of the Seismic Response of Gas Pipelines in Laterally Inhomogeneous Soil. Journal of Geotechnical and Geoenvironmental Engineering, 146(5).
[J.61] Tsinidis, G., di Sarno, L., Sextos, A. G., & Furtner, P. (2020). Optimal intensity measures for the structural assessment of buried steel natural gas pipelines due to seismically-induced axial compression at geotechnical discontinuities. Soil Dynamics and Earthquake Engineering, 131, 106030.
[J.92] Makrakis, N., Psarropoulos, P. N., Sextos, A. G., & Tsompanakis, Y. (2023). Do soft soil layers reduce the seismic kinematic distress of onshore high-pressure gas pipelines? Bulletin of Earthquake Engineering.