Publications
Ctrl/⌘+click opens all the links in a new tab
Dai, S., Zhao, D., Wang, S., Li, K., Jahandari, H., 2022.
Three-dimensional magnetotelluric modelling in a mixed space-wavenumber domain.
Geophysics, 87(4), https://doi.org/10.1190/geo2021-0216.1.
Bastani, M., Wang, S., Malehmir, A., Mehta, S., 2022.
Radio-magnetotelluric and controlled-source magnetotelluric surveys on a frozen lake: opportunities for urban applications in Nordic countries.
Near Surface Geophysics, 20(1), DOI: 10.1002/nsg.12180.
Harmon N., Wang, S., Rychert C.A., Kendall J.M., Constable S., 2021.
Joint Interpretation of Shear Velocity and Resistivity from the PI-LAB Experiment at the Equatorial Mid Atlantic Ridge.
Journal of Geophysical Research: Solid Earth, 126(8), e2021JB022202. DOI: https://doi.org/10.1029/2021JB022202.
Rychert C.A., Tharimena S., Harmon N., Wang, S., Kendall J.M., Constable S., Bogiatzis P., SchlaphorstD., Agius M., Hicks S., 2021.
A dynamic lithosphere-asthenosphere boundary near the equatorial Mid-Atlantic Ridge.
Earth and Planetary Science Letters, 566, https://doi.org/10.1016/j.epsl.2021.116949.
Wang, S., Constable, S., Reyes-Ortega, V., Jahandari, H., Farquharson, C., Avilés-Esquivel, T., 2021.
Two-dimensional determinant inversion of marine magnetotelluric data and a field example from the Gulf of California, Mexico.
Geophysics, 86(1), E37-E57. doi:10.1190/GEO2019-0735.1
Rychert C.A., Harmon N., Constable, S., Wang, S., 2020.
Nature of the Lithosphere-Asthenosphere Boundary
Journal of Geophysical Research: Solid Earth, 125(10), e2018JB016463. DOI:10.1029/2018JB016463
Wang, S., Constable, S., Rychert C.A., Harmon N., 2020.
A lithosphere-asthenosphere boundary and partial melt resolved using marine magnetotelluric data.
Geochemistry Geophysics Geosystems, 21(9), e2020GC009177. https://doi.org/10.1029/2020GC009177
Wang, S., Constable, S., Reyes-Ortega, V., Rychert, C.A., 2019.
A marine magnetotelluric coast effect sensitive to the lithosphere-asthenosphere boundary.
Geophys. J. Int., 218(2), 978-987. DOI:10.1093/gji/ggz202
Wang, S., Bastani, M., Constable, S., Kalscheuer, T., Malehmir, A., 2019.
Using boat-towed radio-magnetotelluric and controlledsource audio-magnetotelluric data to resolve fracture zones at Äspö Hard Rock Laboratory site, Sweden.
Geophys. J. Int., 218(2), 1008-1031. DOI:10.1093/gji/ggz162
Dai, S., Zhao, D., Wang, S., Xiong, B., Zhang, Q., Li, K., Chen, L., Chen, Q., 2019.
Three-dimensional numerical modeling of gravity and magnetic anomaly in a mixed space-wavenumber domain.
Geophysics, 84(4), G41-54. DOI:10.1190/geo2018-0491.1
Li, K., Dai, S., Chen, Q, Zhang, Q., Zhao, D., Wang, S., Ling, J., 2019.
Three-dimensional modeling of magnetic anomaly integral solution in a mixed space-wavenumber domain.
Chinese J. of Geophys., 62(11): 4437-4450, doi:10.6038/cjg2019M0362.
Wang, S., Kalscheuer, T., Bastani, M., Malehmir, A., Pedersen, L.B., Dahlin T., Meqbel, N., 2018.
Joint inversion of lake-floor electrical resistivity tomography and boat-towed radio-magnetotelluric data illustrated on synthetic data and an application from the Äspö Hard Rock Laboratory site, Sweden.
Geophys. J. Int., 213(1), 511-533.
Wang, S., 2017.
Joint inversion and integration of multiple geophysical data for improved models of near-surface structures.
PhD thesis, Uppsala University, Uppsala. ISBN: 978-91-513-0018-4
Brodic, B., Malehmir, A., Bastani, M., Mehta, S., Juhlin, C., Lundberg, E. and Wang, S., 2017.
Multi-component digital-based seismic landstreamer and boat-towed radio-magnetotelluric acquisition systems for improved subsurface characterization in the urban environment.
First Break, 35(8), 41-47.
Wang, S., Malehmir, A., Bastani, M., 2016.
Geophysical characterization of areas prone to quick-clay landslides using radio-magnetotelluric and seismic methods.
Tectonophysics, 677, 248-260.
Malehmir, A., Wang, S., Lamminen, J., Brodic, B., Bastani, M., Vaittinen, K., Juhlin, C., Place, J., 2015.
Delineating structures controlling sandstone-hosted base-metal deposits using high-resolution multicomponent seismic and radio-magnetotelluric methods: a case study from Northern Sweden.
Geophys. Prospect., 63(4), 774-797.
Dai, S., Wang, S., Zhang, Q., Xue, D., 2013.
2.5D forward and inversion of CSEM in frequency domain.
The Chinese Journal of Nonferrous Metals (in Chinese with English abstract), 23(9), 2513-2523.
Wang, S., Xiong, B., Dai, S., 2013.
Resolution ability to E-Ex arrangement wide field electromagnetic method studied on 1-D modeling and inversion.
Journal of Central South University (in Chinese with English abstract), 44(9), 3766-3775.
Wang, S., 2012.
2.5D forward modeling of wide field electromagnetic method with vertical magnetic dipole source.
Master thesis (in Chinese with English abstract), Central South University, Changsha.
Wang, S., Xiong, B., Wang Y., Li C., 2012.
Wave-number domain features of primary field of H-Hz arrangement wild field electromagnetic method.
Journal of Guilin University of Technology (in Chinese with English abstract), 32(2), 179-183.
Wang, S., Xiong, B., 2012.
Numerical calculation methods of wide field apparent resistivity.
Computing Techniques for Geophysical and Geochemical Exploration (in Chinese with English abstract), 34(4), 380-383.
Wang, S., Xiong, B., 2010.
Electromagnetic coupling effect in double frequencies surveys over multi-layer earth.
Computing Techniques for Geophysical and Geochemical Exploration (in Chinese with English abstract), 32(6), 617-620.