The interaction between a semi-infinite underground pipeline and the surrounding soil during longitudinal seismic wave propagation is examined in the article. The wave travels through the soil with its front perpendicular to the pipeline's axis, and the nonlinear laws of interaction (friction) on the surface of their contact, including the Amonton-Coulomb law, are used to solve related wave problems for the pipeline and soil. The method of characteristics and the finite difference method are sequentially used to solve these problems numerically. The implementation of the law of interaction (friction) processes is shown, depending on the parameters of the wave in soil and the mechanical characteristics of soil. It was determined that a wave in soil that involves the pipeline generates a powerful wave in the pipeline. The amplitude of this wave is many times greater than the amplitude of the wave in soil, and it propagates through the pipeline without attenuation. The dependences of the amplitude of this wave on the parameters of the law of friction, waves in soil, and the mechanical characteristics of soil are determined. 

Popov, V.L., Heß, M., 2015, Method of Dimensionality Reduction in Contact Mechanics and Friction, Edition: 1st Publisher: Springer, 253 p.

Sultanov, K.S., 1993, Laws governing the interaction of underground structures with soil during their relative displacement, International Applied Mechanics, 29(3), pp. 217–223.

Sultanov, K.S, Vatin, N.I., 2021, Wave Theory of Seismic Resistance of Underground Pipelines, Applied Sciences, 11(4), 1797.

Kwong, N.S., Jaiswal, K.S., 2023, A Methodology to Combine Shaking and Ground Failure Models for Forecasting Seismic Damage to Buried Pipeline Networks, Bulletin of the Seismological Society of America, 113(6), pp. 2574–2595.

Musa, A.B., 2013, Numerical solution of wave propagation in viscoelastic rods (standard linear solid model), IOP Conference Series: Earth and Environmental Science, 16, 012039.

Fan, K. Liu, J. Wang, J. Jin, C., 2023, Evolution Analysis of Strain Waves for the Fractal Nonlinear Propagation Equation of Longitudinal Waves in a Rod, Fractal and Fractional, 7(8), 586.

Popov, V.L., 2017, Contact Mechanics and friction. Physical principles and applications, 2nd Edition, Springer.

Zhang, R., Wang, C., Li, S., Zhang, J., Liu, W., 2023, Numerical Simulation Study on the Performance of Buried Pipelines under the Action of Faults, Applied Sciences, 13(20), 11266.

Xue, J., Ji, l., 2024, Mechanical Properties of Buried Steel Pipe With Polyurethane Isolation Layer Under Strike-Slip Fault, Journal of Pressure Vessel Technology, Transactions of the ASME, 146(1), 011901.

Yiğit, A., Lav, M.A., Gedikli, A., 2018, Vulnerability of Natural Gas Pipelines under Earthquake Effects, Journal of Pipeline Systems Engineering and Practice, 9(1), 04017036

Demirci, H.E., Karaman, M., Bhattacharya, S., 2021, Behaviour of buried continuous pipelines crossing strike-slip faults: Experimental and numerical study, Journal of Natural Gas Science and Engineering, 92, 103980.

Yang, C., Li, S., 2021, Theoretical analysis and finite element simulation of pipeline structure in liquefied soil, Heliyon, 7(7), e07480.

Boorboor, A., Hosseini, M., 2015, Evaluation of Water Distribution Jointed Pipe Networks under Transient Ground Motions, Open Journal Civil Engineering, 5(2), pp. 190–202.

Boorboor, A., Hosseini, M., 2015, Sensitivity Analysis of Buried Jointed Pipelines Subjected to Earthquake Waves, Open Journal Earthquake Research, 4(2), pp. 74–84.

Izadi, M., Bargi, K., 2019, Improvement of mechanical behavior of buried pipelines subjected to strike-slip faulting using textured pipeline. Frontiers of Structural and Civil Engineering, 13(5), pp. 1105–1119.

Vazouras, P., Dakoulas, P., Karamanos, S.A., 2015, Pipe-soil interaction and pipeline performance under strike-slip fault movements, Soil Dynamics and Earthquake Engineering, 72, pp. 48-65.

Valsamis, A.I., Bouckovalas, G.D., 2020, Analytical methodology for the verification of buried steel pipelines with flexible joints crossing strike-slip faults, Soil Dynamics and Earthquake Engineering, 138, 106280.

Dai, J., Wang, L., Hu, C., Zhang, G., 2021, Experimental Study on Seismic Response of Buried Oil and Gas Pipeline Soil Layers under Lateral Multipoint Excitation, Shock and Vibration, 2021, 9887140.

Huang, D., Tang, A., Wang, Z., 2020, Analysis of pipe-soil interactions using Goodman contact element under seismic action, Soil Dynamics and Earthquake Engineering, 139, 106290.

Sarvanis, G.C., Karamanos, S.A., Vazouras, P., Mecozzi, E., Lucci, A., Dakoulas, P., 2018, Permanent earthquake-induced actions in buried pipelines: Numerical modeling and experimental verification, Earthquake Engineering and Structural Dynamics, 47(4), pp. 966–987.

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, pp. 254–277.

Bakhodirov, A.A., Ismailova, S.I., Sultanov, K.S., 2015, Dynamic deformation of the contact layer when there is shear interaction between a body and the soil, Journal of Applied Mathematics and Mechanics, 79(6), pp. 587–595.

Amabili, M., 2019, Derivation of nonlinear damping from viscoelasticity in case of nonlinear vibrations, Nonlinear Dynamics, 97(3), pp. 1785-1797.

Sultanov, K.S., Khusanov, B.E., Rikhsieva, B.B., 2020, Longitudinal waves in a cylinder with active external friction in a limited area, Journal of Physics: Conference Series, 1546(1), 012140.

Jiao, W., Xu, J., Tian, J., Xie, X., Du, G., 2021, Seismic response analysis of buried pipelines with the high drop, International Journal of Pressure Vessels and Piping, 191, 104379.

Yan, K., Zhang, J., Wang, Z., Liao, W., Wu, Z., 2018, Seismic responses of deep buried pipeline under non-uniform excitations from large scale shaking table test, Soil Dynamics and Earthquake Engineering, 113, pp. 180–192.

Guo, Z., Han, J., Hesham, E., Naggar, M., Hou, B., Zhong, Z., Du, X., 2023, Numerical analysis of buried pipelines response to bidirectional non-uniform seismic excitation, Computers and Geotechnics, 159, 105485.