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Barrett J A, & Ajaev V S (2020) Heat transfer and corner flow in the CVB system. Interfacial Phenomena and Heat Transfer8: 4.BarrettJ AAjaevV S2020Heat transfer and corner flow in the CVB system84Search in Google Scholar
Chakrabarti U, Yasin A, Bellur K, & Allen J S (2023) An investigation of phase change induced Marangoni dominated flow patterns using the CVB data from ISS experiments. Frontiers in Space Technologies4: 1263496.ChakrabartiUYasinABellurKAllenJ S2023An investigation of phase change induced Marangoni dominated flow patterns using the CVB data from ISS experiments41263496Search in Google Scholar
Kundan A, Plawsky JL, Wayner, Jr. PC, Chao DF, Sicker RJ, Motil BJ, Lorik T, Chestney L, Eustace J, and Zoldak J (2015) Thermocapillary phenomena and performance limitations of a wickless heat pipe in microgravity, Phys. Rev. Lett.114: 146105.KundanAPlawskyJLWaynerPCJr.ChaoDFSickerRJMotilBJLorikTChestneyLEustaceJZoldakJ2015Thermocapillary phenomena and performance limitations of a wickless heat pipe in microgravity114146105Search in Google Scholar
Kundan A, Nguyen TTT, Plawsky JL, Wayner, Jr. PC, Chao DF, Sicker RJ (2017) Condensation on highly superheated surfaces: unstable thin films in a wickless heat pipe, Phys. Rev. Lett. 118: 094501.KundanANguyenTTTPlawskyJLWaynerPCJr.ChaoDFSickerRJ2017Condensation on highly superheated surfaces: unstable thin films in a wickless heat pipe118094501Search in Google Scholar
Nguyen TTT, Kundan A, Wayner Jr. PC, Plawsky JL, Chao DF, Sicker RJ (2016) The effect of an ideal fluid mixture on the evaporator performance of a heat pipe in microgravity. IJHMT95: 765–772.NguyenTTTKundanAWaynerPCJr.PlawskyJLChaoDFSickerRJ2016The effect of an ideal fluid mixture on the evaporator performance of a heat pipe in microgravity95765772Search in Google Scholar
Nguyen TTT, Kundan A, Wayner Jr. PC, Plawsky JL, Chao DF, Sicker RJ, (2020) Rip currents: A spontaneous heat transfer enhancement mechanism in a wickless heat pipe. IJHMT149: 11970.NguyenTTTKundanAWaynerPCJr.PlawskyJLChaoDFSickerRJ2020Rip currents: A spontaneous heat transfer enhancement mechanism in a wickless heat pipe14911970Search in Google Scholar
Plawsky JL, Wayner Jr. PC (2012) Explosive nucleation in microgravity: The CVB experiment. IJHMT55: 6473–6484.PlawskyJLWaynerPCJr.2012Explosive nucleation in microgravity: The CVB experiment5564736484Search in Google Scholar
Yu J, Nguyen TT, Pawar A, Wayner Jr. PC, Plawsky JL, Chao DF, Sicker RJ (2021) The effect of condenser temperature on the performance of the evaporator in a wickless heat pipe performance. International Journal of Heat and Mass Transfer176: 121484.YuJNguyenTTPawarAWaynerPCJr.PlawskyJLChaoDFSickerRJ2021The effect of condenser temperature on the performance of the evaporator in a wickless heat pipe performance176121484Search in Google Scholar
Yu J, Pawar A, Plawsky JL, Chao DF (2022) The effect of bubble nucleation on the performance of a wickless heat pipe in microgravity. Npj Microgravity8: 12.YuJPawarAPlawskyJLChaoDF2022The effect of bubble nucleation on the performance of a wickless heat pipe in microgravity812Search in Google Scholar