Relaminarized and recovered turbulence under nonuniform body forces. Physical review fluids, (5)10:104604, American Physical Society, 2020. [PUMA: ubs_40072 ubs_20004 ubs_20010 ubs_40153 ubs_30098 unibibliografie ubs_10004 ubs_30165 ubs_30046 ubs_10006 ubs_20019 wos mult ubs_10021]
Direct numerical simulation of convective heat transfer in porous media. International Journal of Heat and Mass Transfer, (133):11-20, Elsevier, 2019. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_30046 ubs_10006 ubs_20004 wos mult ubs_20010 ubs_40153]
Buoyancy induced turbulence modulation in pipe flow at supercritical pressure under cooling conditions. Physics of Fluids, (30)6:065105, AIP, 2018. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_40072 ubs_30046 ubs_10006 ubs_20004 wos mult ubs_20010 ubs_40153]
A computationally light data-driven approach for heat transfer and hydraulic characteristics modeling of supercritical fluids: From DNS to DNN. International journal of heat and mass transfer, (123):629-636, Elsevier, 2018. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_40072 ubs_30046 ubs_10006 ubs_20004 wos mult ubs_20010 ubs_40153]
Internal convective heat transfer to gases in the low-Reynolds-number "turbulent" range. International Journal of Heat and Mass Transfer, (121):1118-1124, Elsevier, 2018. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_40072 ubs_30046 ubs_10006 ubs_20004 wos ubs_20010 ubs_40153]
Heat transfer prediction of supercritical water with artificial neural networks. Applied thermal engineering, (131):815-824, Elsevier, 2018. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_40072 ubs_30046 ubs_10006 ubs_20004 wos mult ubs_20010 ubs_40153]
A modified convective heat transfer model for heated pipe flow of supercritical carbon dioxide. International journal of thermal sciences, (117):227-238, Elsevier, 2017. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_40072 ubs_30046 ubs_10006 ubs_20004 wos mult ubs_20010 ubs_40153]
Investigation of in-tube cooling of carbon dioxide at supercritical pressure by means of direct numerical simulation. International journal of heat and mass transfer, (114):944-957, Elsevier, 2017. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_40072 ubs_30046 ubs_10006 ubs_20004 wos mult ubs_20010 ubs_40153]
Direct numerical simulation of heated pipe flow with strong property variation. In Wolfgang E. Nagel, Dietmar Kröner, and Michael Resch (Eds.), High performance computing in science and engineering '16 : transactions of the High Performance Computing Center, Stuttgart (HLRS) 2016, 473-486, Springer, Cham, 2016. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_40072 ubs_30046 ubs_10006 ubs_20004 mult swb ubs_20010 ubs_40153]
Direct numerical simulation of strongly heated air flow in a vertical pipe. International journal of heat and mass transfer, (101):1163-1176, Pergamon Press, 2016. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_40072 ubs_30046 ubs_10006 ubs_20004 wos mult ubs_20010 ubs_40153]
Axial heat conduction effects in the thermal entrance region for flows in concentric annular ducts: Correlations for the local bulk-temperature and the Nusselt number at the outer wall. International journal of heat and mass transfer, (103):974-983, Elsevier, 2016. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_40071 ubs_30046 ubs_10006 ubs_20004 wos mult ubs_20010 ubs_40153]
Flow stratification of supercritical CO2 in a heated horizontal pipe. Journal of supercritical fluids, (116):172-189, Elsevier, 2016. [PUMA: ubs_30098 unibibliografie ubs_10004 ubs_40072 ubs_30046 ubs_10006 ubs_20004 wos mult ubs_20010 ubs_40153]