Surface motion of alluvial valley in layered half-space for incident plane P-waves

Zhenning Ba; Jianwen Liang

doi:10.1007/s12209-011-1627-z

Transactions of Tianjin University ›› 2011, Vol. 17 ›› Issue (3) : 157 -165. DOI: 10.1007/s12209-011-1627-z

Article

Surface motion of alluvial valley in layered half-space for incident plane P-waves

Zhenning Ba ¹^,^a
, Jianwen Liang ¹

Author information +

History +

PDF

Abstract

The indirect boundary element method (IBEM) is used to study the surface motion of an alluvial valley in layered half-space for incident plane P-waves based on Wolf’s theory. Firstly, the free field response can be solved by the direct stiffness method, and the scattering wave response is calculated by Green’s functions of distributed loads acting on inclined lines in a layered half-space. The method is verified by comparing its results with literature and numerical analyses are performed by taking the amplification of incident plane P-waves by an alluvial valley in one soil layer resting on bedrock as an example. The results show that there exist distinct differences between the wave amplification by an alluvial valley embedded in layered half-space and that in homogeneous half-space and there is interaction between the valley and the soil layer. The amplitudes are relatively large when incident frequencies are close to the soil layer’s resonant frequencies.

Keywords

layered half-space / alluvial valley / plane P-waves / scattering / one layer over bedrock / indirect boundary element method

Cite this article

Download citation ▾

Zhenning Ba, Jianwen Liang. Surface motion of alluvial valley in layered half-space for incident plane P-waves. Transactions of Tianjin University, 2011, 17(3): 157-165 DOI:10.1007/s12209-011-1627-z

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Trifunac M. D. Surface motion of a semi-cylindrical alluvial valley for incident plane SH waves[J]. Bull Seism Soc Am, 1971, 61(6): 1755-1770.

[2]	Wong H. L., Trifunac M. D. Surface motion of a semi-elliptical alluvial valley for incident plane SH waves[J]. Bull Seism Soc Am, 1974, 64(5): 1389-1408.

[3]	Yuan X., Liao Zhengpeng. Scattering of plane SH waves by a cylindrical alluvial valley of circular-arc crosssection[J]. Earthq Eng Struct Dynam, 1995, 24(10): 1303-1313.

[4]	Liang J., Ba Z., Lee V. W. Diffraction of plane P waves by a shallow circular-arc canyon in a saturated poroelastic half-space[J]. Journal of Tianjin University, 2010, 43(6): 523-529.

[5]	Liang J., Zhang Q., Li Fangjie. Scattering of Rayleigh waves by a shallow circular alluvial valley: High frequency solution[J]. Acta Seismologica Sinica, 2006, 28(2): 176-182.

[6]	Dravinski M. Scattering of plane harmonic SH wave by dipping layers or arbitrary shape[J]. Bull Seism Soc Am, 1983, 73(5): 1303-1319.

[7]	Dravinski M., Mossessian T. K. Scattering of plane harmonic P, SV and Rayleigh waves by dipping layers of arbitrary shape[J]. Bull Seism Soc Am, 1987, 77, 212-235.

[8]	Liang J., Ba Zhenning. Surface motion of an alluvial valley in layered half-space for incident plane SH waves [J]. Journal of Earthquake Engineering and Engineering Vibration, 2007, 27(3): 1-9.

[9]	Liang J., Ba Zhenning. Surface motion of a hill in layered half-space subjected to incident plane SH waves [J]. Journal of Earthquake Engineering and Engineering Vibration, 2008, 28(1): 1-10.

[10]	Liang J., Ba Zhenning. 2.5D scattering of incident plane SV waves by a canyon in layered half-space[J]. Earthquake Engineering and Engineering Vibration, 2010, 9(4): 587-595.

[11]	Sainchez-Sesma F. J., Ramos-Martinez J., Campillo M. An indirect boundary element method applied to simulate the seismic response of alluvial valleys for incident P, S and Rayleigh waves[J]. Earthq Eng Struct Dyn, 1993, 22(4): 279-295.

[12]	Sanchez-Sesma F. J., Campillo M. Diffraction of P, SV and Rayleigh waves by topographic features: A boundary integral formulation[J]. Bull Seism Soc Am, 1991, 81(6): 2234-2253.

[13]	Kawase H., Aki K. A study on the response of a soft basin for incident S, P and Rayleigh waves with special reference to the long duration observed in Mexico City[J]. Bull Seism Soc Am, 1989, 79(5): 1361-1382.

[14]	Kawase H. Time-domain response of a semi-circular canyon for incident SV, P and Rayleigh waves calculated by the discrete wavenumber boundary element method[J]. Bull Seism Soc Am, 1988, 78(4): 1415-1437.

[15]	Semblat J. F., Duval A. M., Dangla P. Modal superposition method for the analysis of seismic-wave amplification [J]. Bull Seism Soc Am, 2003, 93(3): 1144-1153.