[1]J. Sun, Y. Yao, B. Zhang*, A new method for capillary bridge assembly based on flexible template curvature regulation, Acta mechanica Solida Sinica. (2023)
[2] J. Chen, Y. Yao, B. Zhang*, The interface debonding in particle reinforced nonlinear viscoelastic polymer composites, Meccanica.(2022)
[3]Liu, C. Li, B. Zhang*, et al., Simple but Efficient Method To Transport Droplets on Arbitrarily Controllable Paths, Langmuir. (2022)
[4]Zhu, L. Huang, B. Zhang*, et al., Recent progress in optimal design of superhydrophobic surfaces, APL Materials. (2022)
[5]Y.Qiu#, B. Zhang#, J.Yang, et al.,Wafer-scale integration of stretchable semiconducting polymer microstructures via capillary gradient, Nature Communications.(2021)
[6]L. Huang, Y. Yao, B. Zhang* et al., How to Achieve a Monostable Cassie State on a Micropillar-Arrayed
Superhydrophobic Surface, The Journal of Physical Chemistry.(2021)
[7]Wang, Y. Yao, B. Zhang*, Atomistic simulations of the graded residual elastic fields in metallic nanowires, Results in Physics.(2021)
[8]L. Huang, Y. Yao, B. Zhang* et al., One-level microstructure-arrayed hydrophobic surface with low surface adhesion and strong anti-wetting function, Journal of Physics: Condensed Matter.(2021)
[9]Q. An#, B. Zhang#, G. Liu, W. Yang, et al., Directional Droplet-Actuation and Fluid-Resistance Reduction Performance on the Bio-Inspired Shark-Fin-Like Superhydrophobic Surface, Journal of the Taiwan Institute of Chemical Engineers.(2019)
[10]Q. An#, B. Zhang#, X. Zhou, C. Li, et al. Nano-Cones Enhanced Superhydrophobic Fluid-Resistance Reduction and Thermal Isolation Properties of Flexible Pipeline. Heat and Mass Transfer. (2019)
[11]Y. Pi, X. Liu, B. Zhang*, C. Zhang*. Study of hemi-wicking with lattice Boltzmann simulations: A wetting state is dynamically trapped by pinning of imbibition front. AIP Advances (2019)
[12]B. Zhang, F. Meng, J. Feng, et al., Manipulation of colloidal particles in three dimensions via microfluid engineering, Advanced Materials. (2018)
[13]P. Li#, B. Zhang#, H. Zhao, et al., Uni-Directional Droplet Transport on the Biofabricated Butterfly Wing, Langmuir. (2018).
[14]T. Li, X. Liu, H. Zhao, B. Zhang*, L. Wang*, Counterintuitive wetting route of droplet on patterned hydrophilic surface, Europhysics Letters (2018).
[15]Y. Pi, B. Zhang*, Y. Wu, C. Zhang*, Patterning well-controlled cross section of ordered 3D architecture via capillary bridge route, AIP Advances (2018).
[16]B. Zhang, X, Chen, Z. Wang, et al., Spontaneous Wenzel to Cassie dewetting transition on structured surfaces, Physical Review Fluids.(2016)
[17]B. Zhang, Q. Lei, X. Zhang, Droplet can rebound toward both directions on textured surfaces with a wettability gradient, Langmuir. (2015).
[18]B. Zhang, X. Zhang, Elucidating non-wetting of re-entrant surfaces with impinging droplets, Langmuir (2015)
[19]B. Zhang, J. Wang, Z. Liu, X. Zhang, Beyond Cassie equation: Local structure of heterogeneous surfaces determines the contact angles of microdroplets, Scientific Reports.(2014)
[20]B. Zhang, J. Wang, X. Zhang, Effects of the Hierarchical Structure of Rough Solid Surfaces on the Wetting of Microdroplets, Langmuir. (2013)
[21]L. Wang, B. Zhang, X. Wang, et al., Lattice Boltzmann based discrete simulation for gas-solid fluidization, Chemical Engineering Science. (2013)
[22]B. Zhang, L. Wang, X. Wang , X. Zhang, W. Ge, J. Li, Discrete particle simulation of bubbling bed with jet flow at a single orifice based on the lattice Boltzmann method. Chinese Science Bulletin. (2013).
