Wide-angle incidence and P-wave transmission

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Abstract Polarity reversals may occur to transmitted P waves if the incidence angle is greater than the critical incidence angle. We analyze the characteristics of reflection and transmission coefficients under the condition of wide incidence angle based on Zoeppritz equations. We find that for specific conditions, as the incidence angle increases, the characteristic curve of the transmitted P-wave coefficient enters the third quadrant from the first quadrant through the origin, which produces a transition in the transmitted P wave and the corresponding coefficient experiences polarity reversal. We derive the incidence angle when the transmitted P-wave coefficient is zero and verify that it equals zero by using finite-difference forward modeling for a single-interface model. We replace the water in the model reservoir by gas and see that the reservoir P-wave velocity and density decrease dramatically. By analyzing the synthetic seismogram of the transmitted P wave in the single-interface model, we show that the gas-saturated reservoir is responsible for polarity reversal.

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	Articles by authors
	Xie Jun-Fa
	Sun Cheng-Yu
	Lin Mei-Yan
	Li Jing-Jing

Key words： wide-angle reflection Zoeppritz equations incidence angle transmitted P-wave

Received: 2014-09-04;

Fund:

This project is sponsored by: the National Natural Science Foundation of China (No. 41374123).

Cite this article:

Xie Jun-Fa,Sun Cheng-Yu,Lin Mei-Yan et al. Wide-angle incidence and P-wave transmission[J]. APPLIED GEOPHYSICS, 2015, 12(4): 605-614.

[1]	Bregman, N. D., Bailey, R. C., and Chapman, C. H., 1989, Crosshole seismic tomography: Geophysics, 50(2), 200-215.
[2]	Hu, Z. P., Guan, L. P., Gu, L. X., Wang, L. S., Wu, D. L., Dong, Y. R., and Zhao, Q., 2004, Wide angle seismic wave field analysis and imaging method below the high velocity shield layers: Chinese J. Geophys (in Chinese), 47(1), 88-94.
[3]	Liu, F. P., Gao, J., Li, R. Z., Wang, A. L., Chen, H. G., and Yang, C. C., 2008, The influence on normal moveout of total reflected SV-wave by Goos-Hänchen effect at a free surface of stratum: Chinese J. Geophys (in Chinese), 51(3), 862-868.
[4]	Liu, F. P., Meng, X. J., Xiao, J. Q., Wang, A. L., and Yang, C. C., 2012, The Goos-Hänchen shift of wide-angle seismic reflection wave: Sci China Earth Sci (in Chinese), 42(4), 513-519. DOI:10.1007/s11430-011-4344-5.
[5]	Liu, F. P., Wang, A. L., Li, R. Z., Chen, H. G., and Yang, C. C., 2009, The influence on normal moveout of total reflected SH-wave by Goos-Hänchen effect at an interface of strata: Chinese J. Geophys (in Chinese), 52(8), 2128-2134. DOI: 10.3969/j.issn.0001-5733. 2009. 08. 022.
[6]	Majdański, M., 2013, The uncertain in layered models from wide-angle seismic data: Geophysics, 78(3), WB31-WB36.
[7]	Richards, T. C., 1960, Wide angle reflections and their application to finding limestone structures in the foothills of western Canada: Geophysics, XXV(2), 385-407.
[8]	Sain, K., and Kaila, K. L., 1994, Inversion of wide-angle seismic reflection times with damped least squares: Geophysics, 59(11), 1735-1744.
[9]	Sun, C. Y., Ni, C. K., Li, S. J., and Zhang, Y. H., 2007, Feature of wide angle reflection data and correction method: Oil Geophysical Prospecting (in Chinese), 42(1), 24-29.
[10]	Wang, J. H., Li, Q. Z., and Qiu, R., 2003a, Energy shielding action of shallow strong reflection: Oil Geophysical Prospecting (in Chinese), 38(6), 589-596, 602.
[11]	Wang, Z., He, Z. H., Huang, D. J., Wang, X. M., and Du, Z. C., 2003b. The wave-field features researching of wide-angle reflection and the analyzing of forward modeling: Progress in Geophysics (in Chinese), 18(1), 116-121.
[12]	Watremez, L., Lau, K. W. H., Nedimovi?, M. R., and Louden, K. E., 2015, Traveltime tomography of a dense wide-angle profile across Orphan Basin: Geophysics, 80(3), B69-B82.
[13]	Yang, Z. H., Huang, Y. J., and Wu, Y. X., 2012, Wide angle reflections in OBC seismic physical model experiment: Applied Geophysics, 9(2), 207-212.
[14]	Yan, Y. S., Yi, M. L., Wei, X., Wan, W. M., and Chang, L. J., 1998, Cross-borehole seismic Probing in JL 0ill field and the velocity tomography of compressional and shear waves: Oil Geophysical Prospecting (in Chinese), 33(6), 749-757.
[15]	Yan, J. W., Fang, W. B., Cao, H., and Guo, Q. S., 2008, Wave equation migration imaging of cross-well seismic data: Chinese J. Geophys (in Chinese), 51(3), 908-914.
[16]	Zhang, W. P., Guo, P., and Hu, T. Y., 2004, Study and practice of wide-angle seismic data processing: Applied Geophysics, 1(1), 31-37.
[17]	Zhou, B., Greenhalgh, S., and Green, A., 2008, Nonlinear traveltime inversion scheme for crosshole seismic tomography in tilted transversely isotropic media: Geophysics, 37(4), D17-D33.
[18]	Zhu, X., and Mcmechan, G. A., 2015, Amplitude and phase versus angle for elastic wide-angle reflections in the τ-p domain: Geophysics, 80(1), N1-N9.

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