蘭州大學

[1] 甘肅民勤風沙災害與沙化治理技術研究及示范（國家科技支持計劃項目），骨干成員
[2] 復雜環(huán)境與介質(zhì)相互作用的非線性力學(創(chuàng)新研究群體科學基金),主要成員
[3] 風沙流/沙塵暴流場特性及其湍流結構的測量與分析(國家自然科學基金重點項目),骨干成員
[4] 沙漠邊緣時空演化過程跨尺度模型及其仿真研究（國家青年自然科學基金項目），主持
[5] 風沙環(huán)境下高雷諾數(shù)壁湍流結構及其演化機理研究(國家自然科學基金重大項目)，骨干成員

代表性論著：

[1] Bo T L, Zhang H, Zheng X J. Charge-to-mass Ratio of Saltating Particles in Wind-Blown Sand[J]. Scientific reports, 2014, 4.
[2] Fu L T, Bo T L, Zheng X J. Lift-off parameters of saltating particles on Mars[J]. Icarus, 2014, 234: 91-98.
[3] Zhang H, Zheng X J, Bo T L. Electric fields in unsteady wind-blown sand[J]. The European Physical Journal E, 2014, 37(2): 1-12.
[4] Bo T L, Zheng X J. A new expression describing the migration of aeolian dunes[J]. CATENA, 2014, 118: 1-8.
[5] Zhang H, Zheng X J, Bo T. Electrification of saltating particles in wind‐lown sand: Experiment and theory[J]. Journal of Geophysical Research: Atmospheres, 2013, 118(21): 12,086-12,093.
[6] Bo T L, Zhang H, Hu W W, et al. The analysis of electrification in windblown sand[J]. Aeolian Research, 2013, 11: 15-21.
[7] Liu H Y, Bo T L, Wang G H, et al. The Analysis of Turbulence Intensity and Reynolds Shear Stress in Wall-Bounded Turbulent Flows at High Reynolds Numbers[J]. Boundary-Layer Meteorology, 2014, 150(1): 33-47.
[8] Fu L T, Bo T L, Gu H H, et al. Incident Angle of Saltating Particles in Wind-Blown Sand[J]. PloS one, 2013, 8(7): e67935.
[9] Zheng X J, Fu L T, Bo T L. Incident velocity and incident angle of saltating sand grains on Mars[J]. New Journal of Physics, 2013, 15(4): 043014.
[10] o T L, Zhang H, Zhu W, et al. Theoretical prediction of electric fields in wind‐lown sand[J]. Journal of Geophysical Research: Atmospheres, 2013, 118(10): 4494-4502.
[11] Bo T L, Zheng X J. Collision behaviors of barchans in aeolian dune fields[J]. Environmental Earth Sciences, 2013, 70(7): 2963-2970.
[12] Bo T L, Fu L T, Zheng X J. Modeling the impact of overgrazing on evolution process of grassland desertification[J]. Aeolian Research, 2013, 9: 183-189.
[13] Bo T L, Zheng X J. Wind speed-up process on the windward slope of dunes in dune fields[J]. Computers & Fluids, 2013, 71: 400-405.
[14] Bo T L, Zheng X J. Numerical simulation of the evolution and propagation of aeolian dune fields toward a desert–oasis zone[J]. Geomorphology, 2013, 180: 24-32.
[15] Bo T L, Zheng X J. A field observational study of electrification within a dust storm in Minqin, China[J]. Aeolian Research, 2013, 8: 39-47.
[16] Bo T L, Zheng X J. The formation and evolution of aeolian dune fields under unidirectional wind[J]. Geomorphology, 2011, 134(3): 408-416.
[17] Bo T L, Zheng X J. Bulk transportation of sand particles in quantitative simulations of dune field evolution[J]. Powder Technology, 2011, 214(2): 243-251.
[18] Zheng X J, Bo T L, Zhu W. A scale-coupled method for simulation of the formation and evolution of aeolian dune field[J]. International Journal of Nonlinear Sciences and Numerical Simulation, 2009, 10(3): 387-396.
[19] Zheng X J, Bo T L, Xie L. DPTM simulation of aeolian sand ripple[J]. Science in China Series G: Physics, Mechanics and Astronomy, 2008, 51(3): 328-336.
[20] Bo T L, Xie L, Zheng X J. Numerical approach to wind ripple in desert[J]. International Journal of Nonlinear Sciences and Numerical Simulation, 2007, 8(2): 223-228.