RSA CE&C 2015-2021 Group descriptions

32 with respect to the viability of the research program. The group participates in the MCEC Gravitation program, the ARC CBBC and several bilateral collaborations with leading process industries, as well as Industrial Partnership Programs (IPPs) addressing the detailed modeling of electrochemical conversion processes and transport phenomena in dense granular flows. Through participation in these consortia, the group has secured substantial funding to perform research and purchase state-of-the-art high-performance computing (HPC) infrastructure and new MRI flow imaging equipment for the non-invasive monitoring of transport phenomena in porous media. Our group will continue the intensive collaboration with industrial partners originating from different segments (chemical, petrochemical, energy, food and metallurgical) of the process industry. In addition, we aim to obtain funding fromNWO and the ERC tomaintain a healthy balance between projects funded by industry, NWO and ERC. References 1. Yang, L. (Lei), Padding, J.T. (Johan., and Kuipers, J.A.M. (Hans., Modification of kinetic theory of granular flow for frictional spheres, Part I: Two-fluid model derivation and numerical implementation. Chemical Engineering Science (2016) 152, 767–782. 2. Yang, L.L., Padding, J.T.J., and Kuipers, J.A.M.H., Modification of kinetic theory of granular flow for frictional spheres, part II: Model validation. Chemical Engineering Science (2016) 152, 783–794. 3. Tang, Y., Peters, E.A.J.F., and Kuipers, J.A.M., Direct numerical simulations of dynamic gas-solid suspensions. AIChE Journal (2016) 62, 1958–1969. 4. Tang, Y., Lau, Y.M., Deen, N.G., Peters, E.A.J.F., and Kuipers, J.A.M., Direct numerical simulations and experiments of a pseudo-2D gas-fluidized bed. Chemical Engineering Science (2016) 143, 166–180. 5. Maitri, R. V., Das, S., Kuipers, J.A.M., Padding, J.T., and Peters, E.A.J.F., An improved ghost-cell sharp interface immersed boundary method with direct forcing for particle laden flows. Computers and Fluids (2018) 175, 111–128. 6. Mahajan, V. V., Nijssen, T.M.J., Kuipers, J.A.M., and Padding, J.T., Non-spherical particles in a pseudo-2D fluidised bed: Modelling study. Chemical Engineering Science (2018) 192, 1105–1123. 7. Baltussen, M.W., Kuipers, J.A.M., and Deen, N.G., Direct numerical simulation of effective drag in dense gas–liquid– solid three-phase flows. Chemical Engineering Science (2017) 158, 561–568. 8. Mirsandi, H., Rajkotwala, A.H., Baltussen, M.W., Peters, E.A.J.F., and Kuipers, J.A.M., Numerical simulation of bubble formation with a moving contact line using Local Front Reconstruction Method. Chemical Engineering Science (2018) 187, 415–431. 9. Rajkotwala, A.H., Mirsandi, H., Peters, E.A.J.F., Baltussen, M.W., Van Der Geld, C.W.M., Kuerten, J.G.M., and Kuipers, J.A.M., Extension of local front reconstruction method with controlled coalescence model. Physics of Fluids (2018) 30. 10. Masterov, M. V., Baltussen, M.W., and Kuipers, J.A.M., Numerical simulation of a square bubble column using Detached Eddy Simulation and Euler–Lagrange approach. International Journal of Multiphase Flow (2018) 107, 275–288. 11. Kamath, S., Masterov, M. V., Padding, J.T., Buist, K.A., Baltussen, M.W., and Kuipers, J.A.M., Parallelization of a stochastic Euler-Lagrange model applied to large scale dense bubbly flows. Journal of Computational Physics: X (2020) 8, 100058. 12. Finotello, G., Padding, J.T., Deen, N.G., Jongsma, A., Innings, F., and Kuipers, J.A.M., Effect of viscosity on droplet- droplet collisional interaction. Physics of Fluids (2017) 29. 13. Finotello, G., Padding, J.T., Buist, K.A., Schijve, A., Jongsma, A., Innings, F., and Kuipers, J.A.M., Numerical investigation of droplet-droplet collisions in a water and milk spray with coupled heat and mass transfer. Drying Technology (2020) 38, 1597–1619. 14. Patil, A. V., Peters, E.A.J.F., Lau, Y.M., and Kuipers, J.A.M., Modeling 3D Bubble Heat Transfer in Gas-Solid Fluidized Beds Using the CFD-DEM. Industrial and Engineering Chemistry Research (2015) 54, 11466–11474. 15. Patil, A. V., Peters, E.A.J.F., and Kuipers, J.A.M., Comparison of CFD-DEM heat transfer simulations with infrared/ visual measurements. Chemical Engineering Journal (2015) 277, 388–401. 16. Sutkar, V.S., Deen, N.G., Patil, A. V., Salikov, V., Antonyuk, S., Heinrich, S., and Kuipers, J.A.M., CFD-DEM model for coupled heat and mass transfer in a spout fluidized bed with liquid injection. Chemical Engineering Journal (2016) 288, 185–197. 17. Das, S., Panda, A., Patel, H. V., Deen, N.G., and Kuipers, J.A.M., DNS of droplet impact on a solid particle: Effect of wettability on solid conjugate heat transfer. International Journal of Heat and Mass Transfer (2020) 158. 18. Carlos Varas, Á.E., Peters, E.A.J.F., and Kuipers, J.A.M., Computational Fluid Dynamics-Discrete Element Method (CFD-DEM) Study of Mass-Transfer Mechanisms in Riser Flow. Industrial and Engineering Chemistry Research (2017) 56, 5558–5572. 19. Panda, A., Patel, H. V., Peters, E.A.J.F., Baltussen, M.W., and Kuipers, J.A.M., A multiple resolution approach using adaptive grids for fully resolved boundary layers on deformable gas-liquid interfaces at high Schmidt numbers. Chemical Engineering Science (2020) 227.