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浙江大学求是讲席教授,博士生导师
指导11位硕士研究生、23位博士研究生和7位博士后;其中已有19人获博士学位,11人获硕士学位,校级优秀论文9篇;18人次获国家奖学金
据Scopus检索统计,发表论文150余篇,被引10000余次,h-指数47,Elsevier 2021年、2022年和2023年中国高被引学者
Elsevier出版的本专业主要地球物理学杂志Journal of Applied Geophysics主编 (2015-2023)
中国地球物理学会荣誉理事 (2017-), 中国地球物理学会常务理事 (2012-2017)
中国地球物理学会浅地表地球物理专业委员会主席(2014-2022)
EAGE(欧洲地球科学家和工程师学会)浅地表委员会执行委员会成员(2016-)
作为主要的研究人员,所在堪萨斯地质调查所课题组获得2002年“美国勘探地球物理学家学会(SEG)杰出贡献奖”(The Society of Exploration Geophysicists Distinguished Achievement Award) 和2019年美国工程与环境地球物理学家学会“机构贡献奖”(Environmental and Engineering Geophysical Society Institutional Contribution Award),被誉为国际浅层地震技术的引导者。因在高频面波研究中的贡献,获勘探地球物理学家学会浅地表地球物理分会2008年“The Harold Mooney Award”奖。获美国环境与工程地球物理学家学会2008年年会最佳论文奖(Selected Best Paper)和2023年勘探地球物理学家学会“The Leading Edge”最佳论文奖。获2022年中国地球物理学会顾功叙地球物理科技发展奖。受美国勘探地球物理学家学会、美国地球物理学会(AGU)及美国工程与环境地球物理学家学会(EEGS)邀请为专著Advances in Near-surface Seismology and Ground-Penetrating Radar和Journal of Applied Geophysics撰写高频面波方法研究的综述论文。作为特邀人员在环境与工程地球物理国际会议(ICEEG)、美国地球物理学会、美国勘探地球物理学家学会、美国地质学会(GSA)、欧洲地质学家和工程师协会(EAGE)、中国地球物理学会、韩国地球物理学会(KSEG)、台湾大地工程学会等学术会议和学术机构作主旨或特邀报告40。
作为会议主席或副主席,参与筹备和主持了历届在中国举办的环境与工程地球物理国际会议(ICEEG),并使之成为在国际浅层地球物理学界具有重要影响力的学术会议。参与筹备和主持了2013年、2015年和2017年亚太浅地表地球物理会议、2011年韩国地球物理国际研讨会和2015年、2017年、2019年、2021年、2023年和2025年中东工程地球物理国际会议。
学习经历
1973 - 1977成都地质学院(现成都理工大学),勘探地球物理专业
1979 - 1982中国地质科学院研究生院,获武汉地质学院(现中国地质大学)勘探地球物理硕士学位
1989 - 1992 The University of Kansas, USA(美国堪萨斯大学),获地质学(地球物理方向)博士学位。
工作经历
1977 – 1979 成都地质学院任教
1982 – 1986 武汉地质学院任教
1986 – 1989 美国堪萨斯大学堪萨斯地质调查所,访问学者
1992 – 1995 美国堪萨斯大学堪萨斯地质调查所,博士后
1995 – 2001 美国堪萨斯大学堪萨斯地质调查所,助理研究员
2001 – 2007 美国堪萨斯大学堪萨斯地质调查所,副研究员
2007 – 2011 美国堪萨斯大学堪萨斯地质调查所,研究员
2011 – 2016 中国地质大学(武汉)教授,博士生导师
2016 - 至今 浙江大学求是讲席教授,博士生导师
研究领域
从20世纪90年代开始从事浅地表物质地球物理场响应及其应用方面的研究。目前主要研究方向是高频面波方法基础理论和应用地震勘探,计算地球物理和地球物理软件开发。
科研 (2011年以来)
1、利用拉夫波多道分析方法估计近地表横波参数,国家自然科学基金会,2013-2016,负责
2、基于波场分离的高频瑞雷波波形反演方法,国家自然科学基金会,2018-2021,负责
3、城镇环境高频地震面波波场响应和成像,国家自然科学基金会,2019-2023,负责
4、基于深度学习的城市地下介质面波反演,中国国家自然科学基金会,2022-2025,负责
5、杭州地区地下空间混合源面波、智能微动等综合物探调查,中国地质调查局南京地质调查中心,2019-2020,负责
6、西准噶尔克拉玛依后山地区深部地质调查,中国地质调查局,2012-2014,子课题负责
7、面波噪声提取与压制技术, 中石油BGP,2015-2016,负责
8、高频勒夫波反演, 中石油BGP,2015-2016,负责
9、高频瑞利波方法在油气勘探中的应用,中石油BGP,2012-2014,负责
经同行审阅后发表的论文
High-frequency Surface Waves
112. Guan, J., Cheng, F., Xia, J., Mi, B., Sun, H., and Ajo-Franklin, J.B., 2024, Multigrid Spatially Constrained Dispersion Curve Inversion for Distributed Acoustic Sensing (DAS): IEEE Transactions on Geoscience and Remote Sensing, 62, 5932917, 10.1109/TGRS.2024.3443415
111. Guan, B., Xia, J., Liu, Y., Xi, C., Mi, B., Zhang, H., Pang, J., and You, B., 2024, Improving the retri of high-frequency surface waves using convolution-based three-station interferometry for dense linear arrays: Surveys in Geophysics. 45:459–487 https://doi.org/10.1007/s10712-023-09816-6
110. Chen, X., Xia, J., Feng, J., Pang, J., and Zhang, H., 2024, Surface wave inversion using a multi-information fusion neural network: IEEE Transactions on Geoscience and Remote Sensing, 62, 5904613. 10.1109/TGRS.2024.3356663
109. Zhou, J., Mi, B., Xia, J., Zhang, H., Liu, Y., Chen, X., Guan, B., Hong, Y., and Ma, Y., 2024, Noise source localization using deep learning: Geophysical Journal International, 238, 513–536, https://doi.org/10.1093/gji/ggae171
108. Chen, X., Xia, J., Pang, J., and Zhou, C., 2024, Detection of the low-velocity layer using a convolutional neural network on passive surface-wave data: an application in Hangzhou, China: Computers and Geosciences, 190, 105663. https://doi.org/10.1016/j.cageo.2024.105663
107. Hong, Y., Xia, J., Zhang, H., Pang, J., Guan, B., Zhou, J., and Ma, Y., 2024 Azimuth correction for passive surface wave dispersion based on polarization analysis: Geophysical Journal International, 238, 1638–1650, https://doi.org/10.1093/gji/ggae232
106. Guan, B., Xia, J., Pang, J., Liu, Y., Hong, Y., Zhou, J., and Ma, Y., 2024, Improving Data Quality of Three-Component Measurements of Noise in Urban Environments Using Polarization Analysis: IEEE Transactions on Geoscience and Remote Sensing, 62, 5925610, 10.1109/TGRS.2024.3435068
105. Liu, Y., Xia, J., Guan, B., Xi, C., Ning, L., and Zhang, H., 2024, Short-Term Synchronous and Asynchronous Ambient Noise Tomography in Urban Areas: Application to Karst Investigation: Engineering,
104. Zhang, H., Wang, T, Xia, J., Hong, Y., Xi, C., and Le, Z., 2024, Improving the ambient noise cross-correlations using polarization- based azimuth filter: Geophysics,
103. Mi, B., and Xia, J., 2023, Extraction of Rayleigh, Love and Virtual Refraction Waves from 3C High-speed-train-induced Vibrations for Near-surface Characterization: IEEE Transactions on Geoscience and Remote Sensing. 61, 5919710. 10.1109/TGRS.2023.3318989
102. Mi, B., Xia, J., Xu, Y., You, B., and Chen, Y., 2023, Retri of surface waves from high-speed-train-induced vibrations using seismic interferometry: Geophysics, 88(5), KS113 - KS126. https://doi.org/10.1190/geo2022-0603.1
101. Ning, L., Xia, J., Dai, T., Zhang, H., Liu, Y., and Hong, Y., 2023, Improving the quality of high-frequency surface waves retrieved from ultrashort traffic-induced noise based on eigenvalue selection: Geophysical Journal International, 235(3), 2020–2034, https://doi.org/10.1093/gji/ggad343
100. Pang, P., Xia, J., Cheng, F., Zhou, C., Chen, X., Shen, C., Xing, H., and Chang, X., 2023, Surface wave dispersion measurement with polarization analysis using multicomponent seismic noise recorded by 1-D linear array: Surveys in Geophysics, 44, 1863–1895. 10.1007/s10712-023-09787-8
99. Cheng, F., Xia, J., Xi, C., 2023 Artifacts in high-frequency passive surface wave dispersion imaging: Toward the linear receiver array. Surveys in Geophysics, 44, 1009–1039, https://doi.org/10.1007/s10712-023-09772-1
98. Mi, B., and Xia, J., 2023, Inversion of Rayleigh-wave ellipticity for shallow strong-velocity-contrast structures: Geophysics, 88(3), KS89 - KS100. 10.1190/geo2022-0260.1
97. Cheng, F., Xia, J., Xu, Z., and Ajo-Franklin, J. B., 2023, Comparisons between non-interferometric and interferometric passive surface wave imaging methods - towards linear receiver array: Geophysical Journal International, 233(1), 680 – 699. 10.1093/gji/ggac475
96. Liu, Y., Xia, J., Xi, C., Zhang, H., Guan, B., Dai, T., and Ning, L., 2023, Enhancing noise sources in stationary-phase zones for accurate phase-velocity estimation of high-frequency surface waves: Geophysics, 88(1), L1–L9. DOI: https://doi.org/10.1190/geo2021-0696.1
95. Ning, L., Xia, J., Dai, T., Liu, Y., Zhang, H., and Xi, C., 2022, High-frequency surface-wave imaging from traffic-induced noise by selecting inline sources: Surveys in Geophysics. https://doi.org/10.1007/s10712-022-09723-2
94. Chen, X., Xia, J., Pang, J., Zhou, C., and Mi, B., 2022, Deep learning inversion of Rayleigh-wave dispersion curves with geological constraints for near-surface investigations: Geophysical Journal International. 231, 1–14. DOI: https://doi.org/10.1093/gji/ggac171
93. Hu, Y., Pan, Y., and Xia, J., 2022, Wavefield separated full-waveform inversion of shallow-seismic Rayleigh wave: Pure and Applied Geophysics, 179. 1583–1596. https://doi.org/10.1007/s00024-022-02995-0
92. 汪利民,夏江海,罗银河,卞爱飞,2022,浅地表面波成像技术研究进展与展望:地球与行星物理论评,第 53 卷 第 6 期, 613-655. doi: 10.19975/j.dqyxx.2022-008
91. Pang, J., Xia, J., Zhou, C., Chen, X., Cheng, F., and Xing, H., 2022, Common-midpoint two-station analysis of estimating phase velocity using high-frequency ambient noise: Soil Dynamics and Earthquake Engineering, 159, 107356, https://doi.org/10.1016/j.soildyn.2022.107356
90. Zhang, H., Chen, X., Zhang, H., and Xia, J., 2022, Dispersion measurement from ultra-short ambient noise using phase-weighted stacking in urban areas: Journal of Applied Geophysics, 199, 104587. DOI: https://doi.org/10.1016/j.jappgeo.2022.104587
89. Mi, B., Xia, J., Tian, G., Shi, Z., Xing, H., Chang, X., Xi, C., Liu, Y., Ning, L., Dai, T., Pang, J., Chen, X., Zhou, C., and Zhang, H., 2022. Near-surface imaging from traffic-induced surface waves with dense linear arrays: an application in the urban area of Hangzhou, China. Geophysics, 87(2), B145–B158. https://doi.org/10.1190/geo2021-0184.1
88. Zhou, C., Xia, J., Cheng, F., Pang, J., Cheng, X., Xin, H., and Chang, X., 2022. Passive surface-wave waveform inversion for source-velocity joint imaging. Surveys in Geophysics. 43, 853–881. DOI: 10.1007/s10712-022-09691-7
87. Liu, Y., Xia, J., Xi, C., Dai, T., and Ning, L., 2021, Improving the retri of high-frequency surface waves from ambient noise through multichannel-coherency-weighted stack: Geophysical Journal International. 227 (2), 776-785. doi: https://doi.org/10.1093/gji/ggab253
86. Cheng, F., Xia, J., Ajo-Franklin, J.B., Behm, M., Zhou, C., Dai, T., Xi, C., Pang, J., and Zhou, C.W., 2021, High-resolution ambient noise imaging of geothermal reservoir using 3C dense seismic nodal array and ultra-short observation: Journal of Geophysical Research, 126(8), doi: 10.1029/2021JB021827
85. Cheng, F., Xia, J., Xu, Z., and Ajo-Franklin, J.B., 2021, Comparisons between non-interferometric and interferometric passive surface wave imaging methods-Towards linear receiver array: Geophysical Journal International. 226, 256–269. doi: 10.1093/gji/ggab101
84. Zhou, C.J., Xia, J., Pang, J., Cheng, F., Chen, X., Xi, C., Zhang, H., Liu, Y., Ning, L., Dai, T., Mi, B., and Zhou, C.W., 2021, Near surface geothermal reservoir imaging based on the customized dense seismic network: Surveys in Geophysics. 42, 673–697. https://doi.org/10.1007/s10712-021-09642-8
83. Xi, C., Xia, J., Mi, B., Dai, T., Liu, Y., and Ning L., 2021, Modified frequency-Bessel transform method for dispersion imaging of Rayleigh Waves from ambient seismic noise: Geophysical Journal International.225(2), 1271–1280, DOI: https://doi.org/10.1093/gji/ggab008
82. Dai, T., Xia, J., Ning, L., Xi, C., Liu, Y., and Xing, H., 2021, Deep learning for extracting dispersion curves: Surveys in Geophysics. 42, 69–95. DOI: 10.1007/s10712-020-09615-3.
81. Mi, B., Xia, J., Bradford, J. H. and Shen, C., 2020, Estimating near-surface shear-wave-velocity structures via multichannel analysis of Rayleigh and Love waves: An experiment at the Boise Hydrogeophysical Research Site: Surveys in Geophysics, 41 (5), 323-341. DOI: 10.1007/s10712- 019-09582-4.
80. Liu, Y., Xia, J., Cheng, F., Xi, C., Shen, C., and Zhou, C., 2020, Pseudo-linear-array analysis of passive surface waves based on beamforming: Geophysical Journal International, 221, 640-650. doi:10.1093/gji/ggaa024.
79. Cheng, F., Xia, J., Behm, M., Hu, Y., and Pang, J., 2019, Automated data selection in the tau-p domain: Application to passive surface wave imaging: Surveys in Geophysics, 40 (5), 1211-1228.
78. Mi, B., Hu, Y., Xia, J., and Socco, L.V., 2019, Estimation of horizontal-to-vertical spectral ratios (ellipticity) of Rayleigh waves from multistation active-seismic records: Geophysics. 84(6), EN81–EN92, DOI: 10.1190/GEO2018-0651.1.
77. Peng, S., Xia, J., and Cheng, J., 2018, Applications of geophysics in resource detection and environmental protection: Engineering, 4(5), 584-585.
76. Cheng, F., Xia, J., Shen, C., Hu, Y., Xu, Z., and Mi, B., 2018, Imposing active sources during high-frequency passive surface-wave measurement: Engineering, 4(5), 685-693. https://doi.org/10.1016/j.eng.2018.08.003
75. Cheng, F., Xia, J., Xu, Z., and Mi, B., 2018, Frequency-wavenumber (FK)-based data selection in high-frequency passive surface wave survey: Surveys in Geophysics, 39(4), 661-682.
74. Cheng, F., Draganov, D., Xia, J., Hu, Y., and Liu, J., 2018, Q-estimation using seismic interferometry from vertical well data: Journal of Applied Geophysics, 159, 16–22, 10.1016/j.jappgeo.2018.07.019
73. Mi, B., Xia, J., Shen, C., and Wang, L., 2018, Dispersion energy analysis of Rayleigh and Love waves in presence of low-velocity layers in near-surface seismic surveys: Surveys in Geophysics, 39(2), 271– 288.
72. Hu, Y., Xia, J., Mi, B., Cheng, F., and Shen, C., 2018, A pitfall of muting and removing bad traces in surface-wave analysis: Journal of Applied Geophysics, 153. 136–42, https://doi.org/10.1016/j.jappgeo.2018.04.013
71. Xu, Y., Zhang, A., Yang, B., Bao, X., Wang, Q., Xia, J., and Yang, W., 2018, Bridging the connection between effective viscosity and electrical conductivity through water content in the upper mantle: Scientific Reports: 8:1771. DOI:10.1038/s41598-018-20250-2.
70. Gao, L., Pan, Y., Tian, G., and Xia, J., 2018, Estimating Q factor from multi-mode shallow-seismic surface waves: Pure and Applied Geophysics, 175, 2609-2622.
69. Mi, B., Xia, J., Shen, C., Wang, L., Hu, Y., and Cheng, F., 2017, Horizontal Resolution of Multichannel Analysis of Surface Waves: Geophysics. 82 (3), EN51–EN66.
68. Xu, Z., Mikesell, T. D., Xia, J., and Cheng, F., 2017, A comprehensive comparison between the refraction microtremor and seismic interferometry method for phase velocity estimation: Geophysics, 82(6), EN99-EN108.
67. Cheng, F., Xia, J., Luo, Y., Xu, Z., Wang, L., Shen C., Liu R., Pan, Y., Mi, B., and Hu, Y., 2016, Multi-channel analysis of passive surface waves based on cross-correlations: Geophysics. 81, No. 5, EN57-EN66.
66. Pan, Y., Xia, J., Xu, Y., and Gao, L., 2016, Multichannel analysis of Love waves in 3D seismic acquisition system: Geophysics. 81, No. 5, EN67-EN74.
65. Pan, Y., Xia, J., Xu, Y., Xu, Z., Cheng, F., Xu, H., and Gao, L., 2016, Delineating shallow S-wave velocity structure using multiple ambient-noise surface-wave methods: An example from Western Junggar, China: Bulletin of the Seismological Society of America, 106(2), 327-336.
64. Pan, Y., Xia, J., Xu, Y., Gao, L. and Xu, Z., 2016, Love-wave waveform inversion for shallow shear-wave velocity using a conjugate gradient algorithm: Geophysics, 81, no.1, R1-R14.
63. Gao, L., Xia, J., and Pan, Y., and Xu, Y., 2016, Characteristics of high-frequency surface waves in multi-layer earth model: Pure and Applied Geophysics, 173(5), 1627-1638.
62. Xu, Z., Xia, J., Luo, Y., Cheng, F., and Pan, Y., 2016, Misidentification of Love-wave phase velocity based on three-component ambient seismic noise: Pure and Applied Geophysics, 173(4), 1115-1124.
61. Cheng, F., Xia, J., Xu, Y., Xu, Z., and Pan, Y., 2015, A new passive seismic method based on seismic interferometry and multichannel analysis of surface waves: Journal of Applied Geophysics, 117, 126-135.
60. Mi, B., Xia, J., and Xu, Y., 2015, Finite-difference Modeling of SH-wave conversions in shallow shear-wave refraction surveying: Journal of Applied Geophysics, 119, 71–78.
59. Wang, L., Xu, Y., Xia, J., and Luo, Y., 2015, Effect of near-surface topography on high-frequency Rayleigh-wave propagation: Journal of Applied Geophysics, 116, 93-1-3.
58. Luo, Y., Yang, Y., Zhao, K., Xu., Y., and Xia, J., 2015, Unraveling overtone interferences in Love wave phase velocity measurements by Radon transform: Geophysical Journal International. 203(1):327-333.
57. 夏江海,高玲利,潘雨迪,沈超,尹晓菲,2015, 高频面波方法的若干新进展:地球物理学报, 58(8), 2591-6025. (Xia, J., Gao, L. Pan, y., Shen, C., and, Yin, X., 2015, New findings in high-frequency surface wave method: Chine se Journal of Geophysics, 58(8), 2591-6025.)
56. 张煜, 徐义贤, 夏江海, 张双喜, 平萍, 2015, 含流体孔隙介质中面波的传播特性及应用: 地球物理学报, 58, 2759-2778.
55. Yin, X., Xia, J., Shen, C., and Xu, H., 2014, Comparative analysis on penetrating depth of high-frequency Rayleigh and Love waves: Journal of Applied Geophysics, 111, 86–94.
54. Gao, L., Xia, J., and Pan, Y., 2014, Misidentification Caused by Leaky Surface Wave in High-frequency Surface-wave Method: Geophysical Journal International, 199, 1452-1462.
53. Xia, J., 2014, Estimation of near-surface shear-wave velocities and quality factors using multichannel analysis of surface-wave methods: Journal of Applied Geophysics, 103, 140-151.
52. Zhang Y., Xu, Y., Xia, J., Zhang, S., and Ping, P., 2014, On effective characteristic of Rayleigh surface wave propagation in porous fluid-saturated media at low frequencies: Soil Dynamics and Earthquake Engineering, 57, 94-1-3.
51. Zhang, Y., Zhang, S., Xia, J., 2014, Transient responses of porous media under moving surface impulses: International Journal of Solids and Structures, 51, 660-672.
50. Zhang, Y., Xu, Y., Xia, J., Ping, P., and Zhang, S., 2014, On dispersive propagation of surface waves in patchy saturated porous media: Wave Motion, 51, 1225-1236.
49. Xia, J., Yin, X., and Xu, Y., 2013, Feasibility of determining Q of near-surface materials from Love waves: Journal of Applied Geophysics: 95, 47-52.
48. Pan, Y., Xia, J., and Zeng, C., 2013, Verification of correctness of using real part of complex root as Rayleigh-wave phase velocity by synthetic data: Journal of Applied Geophysics, 88, 94-100.
47. Pan, Y., Xia, J., Gao, L., Shen, C., and Zeng, C., 2013, Calculation of Rayleigh-wave phase velocities due to models with a high-velocity surface layer: Journal of Applied Geophysics, 96, 1-6.
46. Xia, J., Xu, Y., Luo, Y., Miller, R.D., Cakir, R., and Zeng, C., 2012, Advantages of using multichannel analysis of Love waves (MALW) to estimate near-surface shear-wave velocity: Surveys in Geophysics, 33(5), 841-860.
45. Xia, J., Xu, Y., Miller, R.D., and Ivanov, J., 2012, Estimation of near-surface quality factors by constrained inversion of Rayleigh-wave attenuation coefficients: Journal of Applied Geophysics, 82, 137-144.
44. Liu, J., Zeng, X., Xia, J., and Mao, M., 2012, The separation of P- and S-wave components from three-component cross-well seismic data: Journal of Applied Geophysics. 82, 163-170.
43. Zeng, C., Xia, J., Miller, R.D., and Tsoflias, G.P., 2012, An improved vacuum formulation for finite-difference modeling of Rayleigh waves including surface topography and internal discontinuity: Geophysics, 77, No. 1, T1-T9.
42. Zeng, C., Xia, J., Miller, R.D., Tsoflias, G.P., and Wang, Z., 2012, Numerical investigation of MASW applications in presence of surface topography: Journal of Applied Geophysics, 84, 52-60.
41. Zhang, Y., Xu, Y., and Xia, J., 2012, Wave fields and spectra of Rayleigh waves in poroelastic media in the exploration seismic frequency band: Advances in Water Resources, 49, 62-71.
40. Zeng, C., Xia, J., Miller, R.D., and Tsoflias, G.P., 2011, Feasibility of waveform inversion of Rayleigh waves for shallow shear-wave velocity using genetic algorithm: Journal of Applied Geophysics, 75, 648-685.
39. Zhang, Y., Xu, Y., and Xia, J., 2011, Analysis of dispersion and attenuation of surface waves in poroelastic media: Geophysical Journal International, 187(2), 871-888.
38. Zhang, K., Luo, Y., Xia, J., and Chen, C., 2011, Pseudospectral modeling and dispersion analysis of Rayleigh waves in viscoelastic media: Soil Dynamics and Earthquake Engineering, 31, 1332-1337.
37. Luo, Y., Xia, J., Xu, Y., and Zeng, C., 2011, Analysis of group-velocity dispersion of high-frequency Rayleigh waves for near-surface applications: Journal of Applied Geophysics, 74, 157-165.
36. Zeng, C., Xia, J., Miller, R.D., and Tsoflias, G.P., 2011, Application of the multiaxial perfectly matched layer (M-PML) to near-surface seismic modeling with Rayleigh waves: Geophysics, 76, no. 3, T43–T52.
35. Xia, J., and Miller, R.D., 2010, Estimation of near-surface shear-wave velocity and quality factor by inversion of high-frequency Rayleigh waves: in Advances in Near-surface Seismology and Ground Penetrating Radar, the publication of Society of Exploration Geophysicists. 17-36. ISBN 978-1- 56080-224-2 (volume) -- ISBN 978-0-931830-41-9 (series)
34. Xia, J., Xu, Y., Miller, R.D., and Zeng, C., 2010, A trade-off solution between model resolution and covariance in surface-wave inversion: Pure and Applied Geophysics, 167(12), 1537-1547.
33. Luo, Y., Xia, J., Xu, Y., Zeng, C., and Liu, J., 2010, Finite-difference modeling and dispersion analysis of high-frequency Love waves for near-surface applications: Pure and Applied Geophysics, 167(12), 1525-1536.
32. Luo, Y., Xia, J., Miller, R.D., Xu, Y., Liu, J., and Liu, Q., 2009, Rayleigh-wave mode separation by high-resolution linear Radon transform: Geophysical Journal International, 179(1), 254-264.
31. Xia, J., Miller, R.D., Xu, Y., Luo, Y., Chen, C., Liu, J., Ivanov, J., and Zeng, C., 2009, High-frequency Rayleigh-wave method: Journal of Earth Science, 20(3), 563-579.
30. Xu, Y., Xia, J., and Miller, R.D., 2009, Approximation to cutoffs of higher modes of Rayleigh waves for a layered earth model: Pure and Applied Geophysics, 166(3), 339-351.
29. Luo, Y., Xia, J., Xu, Y., Zeng, C., Miller, R.D., and Liu, Q., 2009, Dipping Interface mapping using mode-separated Rayleigh waves: Pure and Applied Geophysics, 166(3), 353-374.
28. Luo, Y., Xia, J., Liu, J., Xu, Y., and Liu, Q., 2009, Research on the middle-of-receiver-spread assumption of the MASW method: Soil Dynamics and Earthquake Engineering, 29(1), 71-79.
27. Xia, J., Miller, R.D., and Xu, Y., 2008, Data-resolution matrix and model-resolution matrix for Rayleigh-wave inversion using a damped least-square method: Pure and Applied Geophysics, 165(7), 1227-1248.
26. Luo, Y., Xia, J., Miller, R.D., Xu, Y., Liu, J., and Liu, Q., 2008, Rayleigh-wave dispersive energy imaging by high-resolution linear Radon transform: Pure and Applied Geophysics, 165(5), 903-922.
25. Luo, Y., Xia, J., Liu, J., Xu, Y., and Liu, Q., 2008, Generation of a pseudo-2D shear-wave velocity section by inversion of a series of 1D dispersion curves: Journal of Applied Geophysics, 64(3-4), 115-124.
24. Luo, Y., Xia, J., Liu, J., Liu, Q., and Xu, S., 2007, Joint inversion of high-frequency surface waves with fundamental and higher modes: Journal of Applied Geophysics, 62(4), 375-384.
23. Xia, J., Y. Xu, and R.D. Miller, 2007, Generating image of dispersive energy by frequency decomposition and slant stacking: Pure and Applied Geophysics, 164(5), 941-956.
22. Xia, J., J.E. Nyquist, Y. Xu, M.J.S. Roth, and R.D. Miller, 2007, Feasibility of detecting near-surface feature with Rayleigh-wave diffraction: Journal of Applied Geophysics, 62(3), 244-253.
21. Xu, Y., Xia, J., and Miller, R.D., 2007, Numerical investigation of implementation of air/earth boundary by acoustic/elastic interface approach: Geophysics, 72(5), SM147-SM153.
20. Xia, J., Xu, Y., Miller, R.D., and Chen, C., 2006, Estimation of elastic moduli in a compressible Gibson half-space by inverting Rayleigh wave phase velocity: Surveys in Geophysics, 27(1), 1-17.
19. Xia, J., Xu, Y., Chen, C., Kaufmann, R.D., and Luo, Y., 2006, Simple equations guide high-frequency surface-wave investigation techniques: Soil Dynamics and Earthquake Engineering. 26(5), 395-403.
18. Xu, Y., Xia, J., and Miller, R.D., 2006, Quantitative estimation of minimum offset for multichannel surface-wave survey with actively exciting source: Journal of Applied Geophysics, 59(2), 117-125.
17. Chen, C., Liu, J., Xia, J., and Li, Z., 2006, Integrated geophysical techniques in detecting hidden dangers in river embankments: Journal of Environmental and Engineering Geophysics, 11(2), 83-94.
16. Ivanov, J., Miller, R.D., Xia, J., Steeples, D.W., and Park, C.B., 2006, Joint analysis of refractions with surface waves: An inverse solution to the refraction-traveltime problem: Geophysics, 71(6), R131-R138.
15. Xia, J., Chen, C., Tian, G., Miller, R.D., and Ivanov, J., 2005, Resolution of high-frequency Rayleigh-wave data: Journal of Environmental and Engineering Geophysics, 10(2), 99-110.
14. Kaufmann, R.D., Xia, J., Benson, R., Yuhr, L.B., Casto, D.W., and Park, C.B., 2005, uation of MASW data acquired with a hydrophone streamer in a shallow marine environment: Journal of Environmental and Engineering Geophysics, 10(2), 87-98.
13. Ivanov, J., Park, C.B., Miller, R.D., and Xia, J., 2005, Analyzing and filtering surface-wave energy by muting shot gathers: Journal of Environmental and Engineering Geophysics, 10(3), 307-321.
12. Park, C.B., Miller, R.D., Ryden, N., Xia, J., and Ivanov, J., 2005, Combined use of active and passive surface waves: Journal of Environmental and Engineering Geophysics, 10(3), 323-334.
11. Xia, J., Chen, C., Li, P.H., and Lewis, M.J., 2004, Delineation of a collapse feature in a noisy environment using a multichannel surface wave technique: Geotechnique, 54(1), 17-27.
10. Zhang, S.X., Chan, L.S., and Xia, J., 2004, The selection of field acquisition parameters for dispersion images from multichannel surface wave data: Pure and Applied Geophysics, 161, 185-201.
9. Xia, J., Miller, R.D., Park, C.B., and Tian, G., 2003, Inversion of high frequency surface waves with fundamental and higher modes: Journal of Applied Geophysics, 52(1), 45-57.
8. Tian, G., Steeples, D.W., Xia, J., and Spikes, K.T., 2003, Useful resorting in surface wave method with the autojuggie: Geophysics, 68(6), 1906-1908.
7. Tian, G., Steeples, D.W., Xia, J., Miller, R.D., Spikes, K.T., and Ralston, M.D., 2003, Multichannel analysis of surface wave method with the autojuggie: Soil Dynamics and Earthquake Engineering, 23(3), 243-247.
6. Xia, J., Miller, R.D., Park, C.B., and Tian, G., 2002, Determining Q of near-surface materials from Rayleigh waves: Journal of Applied Geophysics, 51(2-4), 121-129.
5. Xia, J., Miller, R.D., Park, C.B., Wightman, E., and Nigbor, R., 2002, A pitfall in shallow shear-wave refraction surveying: Journal of Applied Geophysics, 51(1), 1-9.
4. Xia, J., Miller, R.D., Park, C.B., Hunter, J.A., Harris, J.B., and Ivanov, J., 2002, Comparing shear-wave velocity profiles from multichannel analysis of surface wave with borehole measurements: Soil Dynamics and Earthquake Engineering, 22(3), 181-190.
3. Xia, J., Miller, R.D., Park, C.B., Hunter, J.A., and Harris, J.B., 2000, Comparing shear-wave velocity profiles from MASW with borehole measurements in unconsolidated sediments, Fraser River Delta, B.C., Canada: Journal of Environmental and Engineering Geophysics, 5(3), 1-13.
2. Xia, J., Miller, R.D., and Park, C.B., 1999, Estimation of near-surface shear-wave velocity by inversion of Rayleigh wave: Geophysics, 64, 691-700.
1. Park, C.B., Miller, R.D., and Xia, J., 1999, Multi-channel analysis of surface waves: Geophysics, 64, 800-808.
Reflection and Refraction
16. Liu, J., Zeng, X., Xia, J., and Mao, M., 2012, The separation of P- and S-wave components from three-component cross-well seismic data: Journal of Applied Geophysics. 82, 163-170.
15. Hunter, J.A., Motazedian, D., Crow, H.L., Brooks, G.R., Miller, R.D., Pugin, A.J-M., Pullan, S.E., and Xia, J., 2010, Near-surface shear wave velocity measurements for soft soil earthquake hazard assessment: Some Canadian mapping examples: in Advances in Near-surface Seismology and Ground Penetrating Radar, the publication of Society of Exploration Geophysicists. 339-360. ISBN 978-1-56080-224-2 (volume) -- ISBN 978-0-931830-41-9 (series)
14. Ivanov, J., Miller, R.D., Xia, J., Dunbar, J.B., and Walters, S., 2010, Refraction nonuniqueness studies at levee sites using the refraction-tomography and JARS methods: in Advances in Near-surface Seismology and Ground Penetrating Radar, the publication of Society of Exploration Geophysicists. 327-338. ISBN 978-1-56080-224-2 (volume) -- ISBN 978-0-931830-41-9 (series)
13. Miller, R.D., Xia, J., and Steeples, D.W., 2009, Seismic reflection characteristics of naturally-induced subsidence affecting transportation: Journal of Earth Science, 20(3), 496-512.
12. Liu, J., J. Xia, Y. Luo, C. Chen, X. Li, and Y. Huang, 2007, Wave field features of shallow vertical discontinuity and their application in non-destructive detection: Journal of Applied Geophysics, 62(3), 270-280.
11. Xia, J., Geier, N.A., Miller, R.D., and Tapie, C.R., 2005, Orthogonal vibroseis sweeps: Geophysical Prospecting, 53(5), 677-688.
10. Miller, R.D., Xia, J., and Park, C.B., 2005, Seismic techniques to delineate dissolution features (Karst) at a proposed power plant site: Soc. Explor. Geophys., Investigations in Geophysics no. 13, Dwain K. Butler, ed., Near-Surface Geophysics, p. 663-679.
9. Miller, R.D., Villella, A., Xia, J., and Steeples, D.W., 2005, Seismic investigation of a salt dissolution feature in Kansas: Soc. Explor. Geophys., Investigations in Geophysics no. 13, Dwain K. Butler, ed., Near-Surface Geophysics, p. 681-694.
8. Liu, J., Xia, J., Chen, C., and Zhang, G., 2005, Accurate elevation and normal moveout corrections of seismic reflection data on rugged topography: New Zealand Journal of Geology and Geophysics, Royal Society of New Zealand. 48(4), 707-716.
7. Ivanov, J., Miller, R.D., Xia, J., Steeples, D.W., and Park, C.B., 2005, The inverse problem of refraction traveltimes, part I: Types of geophysical nonuniqueness through minimization: Pure and Applied Geophysics, 162(3), 447-459.
6. Ivanov, J., Miller, R.D., Xia, J., and Steeples, D.W., 2005, The inverse problem of refraction traveltimes, part II: Quantifying refraction nonuniqueness using a three-layer model: Pure and Applied Geophysics, 162(3), 461-477.
5. Xia, J., and Miller, R.D., 2000, Fast estimation of parameters of a layered-dipping earth model by inverting reflected waves: Journal of Environmental and Engineering Geophysics, 5(2), 21-29.
4. Xia, J., and Miller, R.D., 2000, Design of a hum filter for suppressing power-line noise in seismic data: Journal of Environmental and Engineering Geophysics, 5(2), 31-38.
3. Miller, R.D., and Xia, J., 1998, Large near-surface velocity gradients on shallow seismic reflection data: Geophysics, 63, 1348-1356.
2. Doll, W.E., Miller, R.D., and Xia, J., 1998, A non-invasive shallow seismic source comparison on the Oak Ridge Reservation, Tennessee: Geophysics, 63, 1318-1331.
1. Miller, R.D., Markiewicz, R.D., Merey, C., Xia, J., and Maples, C.G., 1995, Improvements in shallow high resolution seismic reflection through PC based systems: Computers & Geosciences, 21(8), 957-964.
GPR
2. Xia, J., Franseen, E.K., Miller, R.D., and Weis, T.V., 2004, Application of deterministic deconvolution of ground-penetrating radar data in a study of carbonate strata: Journal of Applied Geophysics, 56(3), 213-229
1. Xia, J., Franseen, E.K., Miller, R.D., Weis, T.V., and Byrnes, A.P., 2003, Improving ground-penetrating radar data in sedimentary rocks using deterministic deconvolution: Journal of Applied Geophysics, 54(1-2), 15-33.
Potential Fields
19. KOUADIO, K. L., KOUAME, L. N., DRISSA, C., MI, B*., KOUAMELAN, K. S., GNOLEBA, S. P. D., ZHANG, H., and XIA, J., 2022, Groundwater Flow Rate Prediction from Geo‐Electrical Features using Support Vector Machines: Water Resources Research, DOI: 10.1029/2021WR031623
18. Xia, J., Ludvigson, G., Miller, R.D., Mayer, L., and Haj, A., 2010, Feasibility of delineating a volcanic ash body using electrical resistivity profiling: Journal of Geophysics and Engineering, 7, 267-276.
17. Xia, J., and Miller, R.D., 2007, Integrated geophysical survey in defining subsidence features on a golf course: Journal of Geophysics and Engineering, 4, 443-451.
16. Chen, C., Xia, J., Liu, J., and Feng, G., 2006, Nonlinear inversion of potential-field data using a hybrid-encoding genetic algorithm: Computers and Geosciences, 32(2), 230-239.
15. Xia, J., Doll, W.E., Miller, R.D., Gamey, T.J., and Emond, A.M., 2005, A moving hum filter to suppress rotor noise in high-resolution airborne magnetic data: Geophysics, 70(4), G69-G76.
14. Xia, J., Sprowl, D.R., and Steeples, D.W., 1996, A model of Precambrian geology of Kansas from gravity and magnetic data: Computers & Geosciences, 22, 883-895.
13. Zou, S., Xia, J., and Koussis, A.D., 1996, Analytical solutions to non-fickian subsurface dispersion in uniform groundwater flow: Journal of Hydrology, 179, 237-258.
12. Xia, J., 1996, A geophysical model from potential-field data in Montgomery County: Geophysical Atlas of Kansas Hydrocarbon Pools, Kansas Geological Survey/Kansas Geological Society, Bulletin 237, 17 – 21.
11. Xia, J., and Sprowl, D.R., 1995, Moho depths in Kansas from gravity inversion assuming exponential density contrast: Computers & Geosciences, 21, 237-244.
10. Xia, J., Miller, R.D., and Steeples, D.W., 1995, Aeromagnetic map of Kansas, reduced to the pole with second vertical derivative calculated: Kansas Geological Survey Map Series, M-41A.
9. Xia, J., Miller, R.D., and Steeples, D.W., 1995, Bouguer gravity map of Kansas, second vertical derivative calculated: Kansas Geological Survey Map Series, M-41B.
8. Xia, J., Sprowl, D.R., Steeples, D.W., and Miller, R.D., 1995, Model of Precambrian geology of Kansas: Kansas Geological Survey Map Series, M-41C.
7. Xia, J., Miller, R.D., and Steeples, D.W., 1995, Aeromagnetic map of Kansas, reduced to a horizontal plane and reduced to the pole: Kansas Geological Survey Map Series, M-41D.
6. Xia, J., Miller, R.D., Steeples, D.W., and Adkins-Heljeson, D., 1995, Residual Bouguer gravity map of Kansas, the second order regional trend removed: Kansas Geological Survey Map Series, M-41E.
5. Xia, J., Miller, R.D., Steeples, D.W., and Adkins-Heljeson, D., 1995, Residual aeromagnetic map of Kansas, second order regional trend removed: Kansas Geological Survey Map Series, M-41F.
4. Xia, J., Sprowl, D.R., and Adkins-Heljeson, D., 1993, Correction of topographic distortions in potential-field data: a fast and accurate approach: Geophysics, 58, 515-523.
3. Xia, J., and Sprowl, D.R., 1992, Inversion of potential field data by iterative forward modeling in the wavenumber domain: Geophysics, 57, 126-130.
2. Xia, J., Yarger, H., Lam, C., Steeples, D.W., and Miller, R.D., 1992, Bouger gravity map of Kansas: Kansas Geological Survey Map Series, M-31.
1. Xia, J., and Sprowl, D.R., 1991, Correction of topographic distortions in gravity data: Geophysics, 56, 537-541.
