2001年获中国科学技术大学地球与空间科学系本科学位，2011年于美国密苏里大学哥伦比亚分校地质科学系获博士学位。2019年加入南方科技大学地球与空间科学系。主要研究方向为地球物理反演和结构成像。在Geophysical Research Letters等国际核心期刊上发表学术论文二十余篇。现主持国家自然科学基金面上项目2项，参与国家自然科学基金重大研究计划集成项目1项，曾共同主持国外国家级科研项目2项。

教育背景

2005.08-2011.12，博士，美国密苏里大学哥伦比亚分校，地质科学系

2001.09-2005.07，硕士，中国科学技术大学，地球与空间科学系

1997.09-2001.07，学士，中国科学技术大学，地球与空间科学系

工作经历

2019.01-至今，南方科技大学，地球与空间科学系

2014.12-2019.01，美国罗德岛大学，海洋学院

2014.01-2014.12，美国布朗大学，地球、环境与空间科学系

2011.11-2013.12，美国波士顿大学，地球与环境科学系

教学

地球物理反演理论基础（大三课程）：主要讲述线性反演的基本理论和在重磁电震地球物理方法中的简单应用和机器学习的基本数学知识。

地球物理反演理论（研究生课程）：主要讲述地球物理线性和非线性反演的理论和应用。

研究领域

地震学全波形正反演，地震波衰减和各向异性反演，洋中脊、青藏高原等构造活动区地球物理研究。

最近发表论文

25. Liu, Bao*, Zhu, and Li (2024). Review of rock-physics studies of the attenuation in natural gas hydrate-bearing sediments, Reviews of Geophysics and Planetary Physics (in Chinese), 55, 369-380.

24. Wang*, Yang*, Shen*, Bao, and Li (2023). 3D sensitivity kernels with full attenuation computed by a combination of the strong stability preserving Runge-Kutta method and the scattering-integral method, Journal of Geophysical Research: Solid Earth, 128(8).

23. Wang, Hu, Bao, Yu, Yang, Chen* (2023). Global seismic tomography reveals remnants of subducted Tethyan oceanic slabs in the deep mantle, Science China Earth Sciences, 66, 2751-2769.

22. Dai, Bao*, Sun, and Shan (2023). A novel method to estimate orientations of an ocean-bottom seismometer array for accurate measurement of waveform phases and amplitudes, Seismological Research Letters.

21. Liu, Bao*, and Guo (2022). Modeling of seismic attenuation infracture-filling gas hydrate-bearing sediments and its application to field observations in the Krishna-Godavari Offshore Basin, India. Marine And Petroleum Geology, 141.doi: 10.1016/j.marpetgeo.2022.105698

20. Dai, Shan, Meng, and Bao* (2022). Review of progress in seismic attenuation tomography. Reviews of Geophysics and Planetary Physics, 53(6):702-720 (in Chinese). doi:10.19975/j.dqyxx.2022-028.

19. Bao*, Guo*, and Shen* (2021)， Compositional Variation in the Crust of Peninsular Ranges and Surrounding Regions, Southern California, Revealed by Full-Wave Seismic and Gravity Joint Inversion. Journal Of Geophysical Research-solid Earth,126(12)

18. Sun, Zhang, Ren, Bao, Xu, Sun, Yang, and Chen* (2021)， 3d seismic-wave modeling with a topographic fluid–solid interface at the sea bottom by the curvilinear-grid finite-difference method. Bulletin Of The Seismological Society Of America, 111(5), 2753-277

17. Bao*, and Shen* (2020), Early-stage lithospheric foundering beneath the eastern Tibetan Plateau revealed by full-wave Pn tomography, Geophysical Research Letters, 47, doi: 10.1029/2019GL086469

16. Wang*, Shen*, Bao, and Flinders (2019), Locating shallow seismic sources with waves scattered by surface topography: Validation of the method at the Nevada Test Site, JGR-Solid Earth, 124, doi:10.1029/2018JB017291

15. Emry*, Shen, Nyblade, Flinders, and Bao (2019), Upper mantle Earth structure in Africa from full-wave ambient noise tomography, G3, 20, 120-147,doi:10.1029/2018GC007804

14. Bao*, and Shen (2018), Full-waveform sensitivity kernels of component-differential traveltimes and ZH amplitude ratios for velocity and density tomography, JGR-Solid Earth, 

13. Dalton*, Bao, and Ma (2017), The thermal structure of cratonic lithosphere from global Rayleigh wave attenuation, EPSL, doi: 10.1016/j.epsl.2016.10.014

12. Bao*, and Shen (2016), Assessing waveform predictions of recent three-dimensional velocity models of the Tibetan Plateau, JGR-Solid Earth

11. Bao*, Dalton, Jin, Gaherty, and Shen (2016), Imaging Rayleigh wave attenuation with USArray, Geophysical Journal International

10. Bao*, Dalton, and Ritsema (2016), Effects of elastic focusing on global models of Rayleigh wave attenuation, Geophysical Journal International

9. Kaviani*, Sandvol, Bao, Rumpker, and Gok (2015), The structure of the crust in the Turkish-Iranian Plateau and Zagros using Lg Q and velocity, Geophysical Journal International, 200, 1254-1268, doi:10.1093/gji/ggu468

8. Bao*, Sandvol, Chen, Ni, Hearn, and Shen (2012), Azimuthal anisotropy of Lg attenuation in eastern Tibetan Plateau, JGR, 117, B10309, doi:10.1029/2012JB009255

7. Sahin*, Bao, Turkelli, Sandvol, Teoman, and Kahraman (2012), Lg wave attenuation in the Isparta Angle and Anatolian Plateau, Pageoph, 170, 337-351, doi:10.1007/s00024-012-0517-1

6. Bao*, Sandvol, Ni, Hearn, Ceylan, Liang, and Phillips (2012), High resolution seismic velocity and attenuation models of eastern Tibet and adjacent regions, Proceedings of the 33nd Monitoring Research Review of Ground-Based Nuclear Explosion Monitoring Technologies, Tucson, AR

5. Bao*, Sandvol, Ni, Hearn, Chen, and Shen (2011), High resolution regional seismic attenuation tomography in eastern Tibetan Plateau and adjacent areas, GRL, 38, L16304, doi.10.1029/2011GL048012

4. Bao*, Sandvol, Zor, Sahin, Mohamad, Gok, Mellors, Godoladze, Yetirmishli, and Turkelli (2011), Pg attenuation tomography within the northern Middle East, BSSA, 101-4,1496-1506, doi: 10.1785/0120100316

3. Shi, Wen, Bao, Li, and Huang (2006), Application of rock creep experiment in calculating the viscoelastic parameters of earth medium, Science in China (D)-Earth Science, 49, 492-498, doi:10.1007/s11430-006-0492-4.

2. Bao, Shi, Wen, and Li (2005), Experiment study and interpretation on relation between modulus of rocks and strain amplitude, Earthquake Research in China, 21(4) 

1. Bao, and Shi (2004), Experiment study on nonlinear elasticity of rocks and P-M Model, Chinese Journal of Rock Mechanics and Engineering, 23, 3397