@article{yan_zhang_liu_ye_yu_chen_wang_zhang_hu_kang_et al._2019, title={Shape-controlled synthesis of liquid metal nanodroplets for photothermal therapy}, volume={12}, ISSN={["1998-0000"]}, DOI={10.1007/s12274-018-2262-y}, number={6}, journal={NANO RESEARCH}, author={Yan, Junjie and Zhang, Xudong and Liu, Yang and Ye, Yanqi and Yu, Jicheng and Chen, Qian and Wang, Jinqiang and Zhang, Yuqi and Hu, Quanyin and Kang, Yang and et al.}, year={2019}, month={Jun}, pages={1313–1320} }
 @article{liu_li_hu_wiltberger_ryll_2014, title={Effects of Bubble-Liquid Two-Phase Turbulent Hydrodynamics on Cell Damage in Sparged Bioreactor}, volume={30}, ISSN={["1520-6033"]}, url={http://www.scopus.com/inward/record.url?eid=2-s2.0-84893793023&partnerID=MN8TOARS}, DOI={10.1002/btpr.1790}, abstractNote={According to recent experimental studies on sparged bioreactors, significant cell damage may occur at the gas inlet region near the sparger. Although shear stress was proposed to be one of the potential causes for cell damage, detailed hydrodynamic studies at the gas inlet region of gas–liquid bioreactors have not been performed to date. In this work, a second‐order moment (SOM) bubble–liquid two‐phase turbulent model based on the two‐fluid continuum approach is used to investigate the gas–liquid hydrodynamics in the bubble column reactor and their potential impacts on cell viability, especially at the gas inlet region. By establishing fluctuation velocity and bubble–liquid two‐phase fluctuation velocities correlation transport equations, the anisotropy of two‐phase stresses and the bubble–liquid interactions are fully considered. Simulation results from the SOM model indicate that shear and normal stresses, turbulent energy dissipation rate, and the turbulent kinetic energy are generally smaller at the gas inlet region when compared with those in the fully developed region. In comparison, a newly proposed correlation expression, stress‐induced turbulent energy production (STEP), is found to correlate well with the unusually high cell death rate at the gas inlet region. Therefore, STEP, which represents turbulent energy transfer to a controlled volume induced by a combination of shear and normal stresses, has the potential to provide better explanation for increased cell death at the sparger region. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 30:48–58, 2014}, number={1}, journal={BIOTECHNOLOGY PROGRESS}, author={Liu, Yang and Li, Fanxing and Hu, Weiwei and Wiltberger, Kelly and Ryll, Thomas}, year={2014}, month={Jan}, pages={48–58} }
 @article{li_liu_liu_2014, title={Investigation on swirling gas-particle hydrodynamics using an improved momentum transfer coefficient}, volume={15}, number={1}, journal={International Journal of Nonlinear Sciences and Numerical Simulation}, author={Li, G. H. and Liu, Y. and Liu, J.}, year={2014}, pages={47–55} }
 @article{lomenzo_takmeel_zhou_liu_fancher_jones_moghaddam_nishida_2014, title={The effects of layering in ferroelectric Si-doped HfO2 thin films}, volume={105}, number={7}, journal={Applied Physics Letters}, author={Lomenzo, P. D. and Takmeel, Q. and Zhou, C. Z. and Liu, Y. and Fancher, C. M. and Jones, J. L. and Moghaddam, S. and Nishida, T.}, year={2014} }