[1] Kaneyasu N, Ohashi H, Suzuki F, et al. Weak size dependence of resuspended radiocesium adsorbed on soil particles collected after the Fukushima nuclear accident[J]. Journal of Environmental Radioactivity, 2017, 172: 122-129. [2] Johnston P N, Williams G A, Burns P A, et al. Plutonium resuspension and airborne dust loadings in the desert environment of Maralinga, South Australia[J]. Journal of Environmental Radioactivity, 1993, 20(2): 117-131. [3] Bergström L. Hamaker constants of inorganic materials[J]. Advances in Colloid and Interface Science, 1997, 70: 125-169. [4] Wiechert A I, Hunter B W, Szakas S E, et al. Selective capture and recovery of uranium oxide colloids from aqueous soil suspensions using high gradient magnetic filtration[J]. Separation and Purification Technology, 2025, 379: 135042. [5] ZHANG Le, SUN Bo, ZHANG Qili, et al. First-principles study of the hydrogen resistance mechanism of PuO2[J]. ACS Omega, 2020, 5(13): 7211-7218. [6] Loosmore G A. Evaluation and development of models for resuspension of aerosols at short times after deposition[J]. Atmospheric Environment, 2003, 37(5): 639-647. [7] IAEA. Handbook of parameter values for the prediction of radionuclide transfer in terrestrial and freshwater environments: Technical Reports Series No 472[R]. Vienna: IAEA, 2010. [8] UNSCEAR. Methodology for estimating human exposures due to radioactive discharges: A/AC. 82/R. 702[R]. Vienna: UNSCEAR, 2014. [9] Henry C, Minier J P, Brambilla S. Particle resuspension: challenges and perspectives for future models[J]. Physics Reports, 2023, 1007: 1-98. [10] Reeks M W, Hall D. Kinetic models for particle resuspension in turbulent flows: theory and measurement[J]. Journal of Aerosol Science, 2001, 32(1): 1-31. [11] CUI Yan, Sommerfeld M. Lattice-Boltzmann simulations for analysing the detachment of micron-sized spherical particles from surfaces with large-scale roughness structures[J]. Particuology, 2022, 61: 47-59. [12] Rettinger C, Eibl S, Rüde U, et al. Rheology of mobile sediment beds in laminar shear flow: effects of creep and polydispersity[J]. Journal of Fluid Mechanics, 2022, 932: A1. [13] LIU Hao, Bossy M, Vowinckel B, et al. Particle resuspension from complex multilayer deposits by laminar flows: Statistical analysis and modeling[J]. International Journal of Multiphase Flow, 2025, 184: 105115. [14] Henry C, Minier J P. Progress in particle resuspension from rough surfaces by turbulent flows[J]. Progress in Energy and Combustion Science, 2014, 45: 1-53. [15] Grohn P, Heinrich S, Antonyuk S. Numerical investigation of the particle dynamics in a rotorgranulator depending on the properties of the coating liquid[J]. Pharmaceutics, 2023, 15(2): 469. [16] QIN Mingyang, JIN Yu, LUO Weiwen, et al. Measurement and CFD-DEM simulation of suspension velocity of peanut and clay-heavy soil at harvest time[J]. Agronomy, 2023, 13(7): 1735. [17] Khademishamami M, Sanford L, Nardin W, et al. Direct interception of particles by a vegetation stem with varying adhesive forces[J]. Journal of Geophysical Research: Earth Surface, 2025, 130(6): e2024JF007915. [18] Lecrivain G, Vitsas A, Boudouvis A G, et al. Simulation of multilayer particle resuspension in an obstructed channel flow[J]. Powder Technology, 2014, 263: 142-150. [19] Cundall P A. A computer model for simulating progressive large scale movements in blocky rock systems[C]//Proceedings of Symposium of International Society of Rock Mechanics. Nancy: Society for Rock Mechanics, 1971: II-8. [20] Israelachvili J N. Intermolecular and surface forces[M]. New York: Academic Press, 1991. [21] Hertz H. Ueber die Berührung fester elastischer Körper[M]//Colding T, Huybrechts D, Hwang J M, et al. Journal für die reine und angewandte Mathematik Band 92. Berlin: De Gruyter, 1881: 156-171. [22] Hertz H. Ueber die Berührung fester elastischer Körper[M]//Verhandlungen des Vereins zur Beförderung des Gewerbfleißes. Berlin : Verein zur Beförderung des Gewerbefleisses, 1882: 449-463. [23] Heinrich H. Miscellaneous papers[M]. London: Macmillan, 1896. [24] Derjaguin B V, Muller V M, Toporov Y P. Effect of contact deformations on the adhesion of particles[J]. Journal of Colloid and Interface Science, 1975, 53(2): 314-326. [25] Johnson K L, Kendall K, Roberts A D. Surface energy and the contact of elastic solids[J]. Proceedings of the Royal Society of London a, 1971, 324(1558): 301-313. [26] Tabor D. Surface forces and surface interactions[J]. Journal of Colloid and Interface Science, 1977, 58(1): 2-13. [27] Angelidakis V, Boschi K, Brzeziński K, et al. YADE-an extensible framework for the interactive simulation of multiscale, multiphase, and multiphysics particulate systems[J]. Computer Physics Communications, 2024, 304: 109293. [28] Dietzel M, Sommerfeld M. Numerical calculation of flow resistance for agglomerates with different morphology by the lattice-Boltzmann method[J]. Powder Technology, 2013, 250: 122-137. [29] Latt J, Malaspinas O, Kontaxakis D, et al. Palabos: parallel lattice Boltzmann solver[J]. Computers & Mathematics with Applications, 2021, 81: 334-350. [30] FENG Zhigang, Michaelides E E. Proteus: a direct forcing method in the simulations of particulate flows[J]. Journal of Computational Physics, 2005, 202(1): 20-51. [31] ZHANG Hua, LIU Yaguang, ZHANG Zehua, et al. An immersed boundary-lattice Boltzmann flux solver for simulation of flows around structures with large deformation[J]. Physics of Fluids, 2023, 35(3): 031912. [32] Holm B, Ahuja R. Ab initio calculation of elastic constants of SiO2 stishovite and α-quartz[J]. The Journal of Chemical Physics, 1999, 111(5): 2071-2074. [33] HUANG Zhiyuan, MA Lidong, ZHANG Jianbao, et al. First-principles study of elastic and thermodynamic properties of UO2, γ-UO3 and α-U3O8[J]. Journal of Nuclear Materials, 2022, 572: 154084. |