International Journal List
[23] Kwon CH, HS Kwon, Hu Oh, Jung EG, Experimental investigation on acceleration of working fluid of heat pipe under bypass line operation , Case Studies in Thermal Engineering 2023, Vol. 53. 103742 (SCIE indexed, IF: 6.8, JCR < 10%)
[23] Kwon CH, HS Kwon, Hu Oh, Jung EG, Experimental investigation on acceleration of working fluid of heat pipe under bypass line operation , Case Studies in Thermal Engineering 2023, Vol. 53. 103742 (SCIE indexed, IF: 6.8, JCR < 10%)
[22] Kwon CH, Kwon HS, Jung EG, An experimental investigation on the influence of condenser bypass area for the transient and steady-state heat-transfer performance of heat pipes , International Communication in Heat and Mass Transfer 2023, Vol. 148, 107057 (SCIE indexed, IF: 7, JCR < 2%)
[22] Kwon CH, Kwon HS, Jung EG, An experimental investigation on the influence of condenser bypass area for the transient and steady-state heat-transfer performance of heat pipes , International Communication in Heat and Mass Transfer 2023, Vol. 148, 107057 (SCIE indexed, IF: 7, JCR < 2%)
[21] Kwon CH, Jin GC, Kim JH, IM BG, Jeong JH, Jung EG, Influence of condenser bypass port area on maximum thermal load of heat pipe , International Communication in Heat and Mass Transfer 2023, Vol. 148, 107006 (SCIE indexed, IF: 7, JCR < 2%)
[21] Kwon CH, Jin GC, Kim JH, IM BG, Jeong JH, Jung EG, Influence of condenser bypass port area on maximum thermal load of heat pipe , International Communication in Heat and Mass Transfer 2023, Vol. 148, 107006 (SCIE indexed, IF: 7, JCR < 2%)
[20] Jung EG, Mathematical modeling for loop heat pipe using thin-film theory, ENERGY 2023, under review(SCIE indexed, IF: 8.857, JCR < 5%)
[20] Jung EG, Mathematical modeling for loop heat pipe using thin-film theory, ENERGY 2023, under review(SCIE indexed, IF: 8.857, JCR < 5%)
[19] Kwon JH, Jung EG, Overshoot temperature control on evaporator wall of loop heat pipe for space vehicle thermal control through bypass line under high thermal load, Applied Thermal Engineering 2023, Vol. 129, 119776 (SCIE indexed, IF: 6.465, JCR < 5%)
[19] Kwon JH, Jung EG, Overshoot temperature control on evaporator wall of loop heat pipe for space vehicle thermal control through bypass line under high thermal load, Applied Thermal Engineering 2023, Vol. 129, 119776 (SCIE indexed, IF: 6.465, JCR < 5%)
[18] Baek YM, Jung EG, Heat transfer performance of loop heat pipe for space vehicle thermal control under bypass line operation, International Journal of Heat and Mass Transfer 2022/09, Vol. 195, 123064(SCIE indexed, IF: 5.431, JCR < 10%)
[18] Baek YM, Jung EG, Heat transfer performance of loop heat pipe for space vehicle thermal control under bypass line operation, International Journal of Heat and Mass Transfer 2022/09, Vol. 195, 123064(SCIE indexed, IF: 5.431, JCR < 10%)
[17] Baek YM, Jung EG, Experimental study on start-up and steady-state heat transfer performance of heat pipe with liquid bypass line for accelerating working fluid, Case Studies in Thermal Engineering 2022/01, Vol. 29, 101708(SCIE indexed, IF: 6.268, JCR < 10%)
[17] Baek YM, Jung EG, Experimental study on start-up and steady-state heat transfer performance of heat pipe with liquid bypass line for accelerating working fluid, Case Studies in Thermal Engineering 2022/01, Vol. 29, 101708(SCIE indexed, IF: 6.268, JCR < 10%)
[16] Jung EG, Boo JH, Enhancement of the maximum heat transfer rate of the heat pipe through the bypass line, Applied Thermal Engineering 2021, Vol. 198, 117461(SCIE indexed, IF: 6.465, JCR < 5%)
[16] Jung EG, Boo JH, Enhancement of the maximum heat transfer rate of the heat pipe through the bypass line, Applied Thermal Engineering 2021, Vol. 198, 117461(SCIE indexed, IF: 6.465, JCR < 5%)
[15] Sung JP, Boo JH, Jung EG, Transient thermodynamic modeling of a scroll compressor Using R22 refrigerant, ENERGIES 2020/08, 3911 (SCIE indexed, IF: 3.252, JCR < 45%)
[15] Sung JP, Boo JH, Jung EG, Transient thermodynamic modeling of a scroll compressor Using R22 refrigerant, ENERGIES 2020/08, 3911 (SCIE indexed, IF: 3.252, JCR < 45%)
[14] Jung EG, Boo JH, Experimental observation of thermal behavior of a loop heat pipe with a bypass line under high heat flux, ENERGY 2020/04, 117241(SCIE indexed, IF: 8.857, JCR < 5%)
[14] Jung EG, Boo JH, Experimental observation of thermal behavior of a loop heat pipe with a bypass line under high heat flux, ENERGY 2020/04, 117241(SCIE indexed, IF: 8.857, JCR < 5%)
[13] Jung EG, Boo, JH, Overshoot elimination of the evaporator wall temperature of a loop heat pipe through a bypass line, Applied Thermal Engineeing 2020/01, Vol. 165, 114594(SCIE indexed, IF: 6.465, JCR < 5%)
[13] Jung EG, Boo, JH, Overshoot elimination of the evaporator wall temperature of a loop heat pipe through a bypass line, Applied Thermal Engineeing 2020/01, Vol. 165, 114594(SCIE indexed, IF: 6.465, JCR < 5%)
[12] Jung EG, Boo, JH, A novel transient thermohydraulic model of a micro heat pipe, International Journal of Heat and Mass Transfer 2019/09, Vol. 140, pp. 819-827(SCIE indexed, IF: 5.431, JCR < 10%)
[12] Jung EG, Boo, JH, A novel transient thermohydraulic model of a micro heat pipe, International Journal of Heat and Mass Transfer 2019/09, Vol. 140, pp. 819-827(SCIE indexed, IF: 5.431, JCR < 10%)
[11] Jung EG, Boo, JH, A novel transient thermohydraulic model of micro-channel heat sink, Journal of Heat and Mass Transfer 2019/12, Vol. 145, 118772(SCIE indexed, IF: 5.431, JCR < 10%)
[11] Jung EG, Boo, JH, A novel transient thermohydraulic model of micro-channel heat sink, Journal of Heat and Mass Transfer 2019/12, Vol. 145, 118772(SCIE indexed, IF: 5.431, JCR < 10%)
[10] Jung EG, Boo, JH,A novel analytical modeling of a loop heat pipe employing the thin-film theory: part I-modeling and simulation, ENERGIES 2019/06, Vol. 12, 2408(SCIE indexed,IF: 3.252, JCR < 45%)
[10] Jung EG, Boo, JH,A novel analytical modeling of a loop heat pipe employing the thin-film theory: part I-modeling and simulation, ENERGIES 2019/06, Vol. 12, 2408(SCIE indexed,IF: 3.252, JCR < 45%)
[9] Jung EG, Boo, JH, A novel analytical modeling of a loop heat pipe employing thin-film theory: part II-experimental validation, ENERGIES 2019/06, Vol. 12, 2403(SCIE indexed, IF: 3.252, JCR < 45%)
[9] Jung EG, Boo, JH, A novel analytical modeling of a loop heat pipe employing thin-film theory: part II-experimental validation, ENERGIES 2019/06, Vol. 12, 2403(SCIE indexed, IF: 3.252, JCR < 45%)
[8] Jung EG, Boo, JH, A numerical modeling for the steady-state performance of a micro heat pipe using thin liquid film theory, Journal of Heat and Mass Transfer 2018/05, Vol. 126, pp. 557-566(SCIE indexed, IF: 5.431, JCR < 10%)
[8] Jung EG, Boo, JH, A numerical modeling for the steady-state performance of a micro heat pipe using thin liquid film theory, Journal of Heat and Mass Transfer 2018/05, Vol. 126, pp. 557-566(SCIE indexed, IF: 5.431, JCR < 10%)
[7] Jung EG, Boo, JH, A numerical study on the heat and mass transfer of a micro heat pipe with a phase-change interface analysis, Heat and Mass Transfer 2017/11, Vol. 53, pp. 3363-3372(SCIE indexed, IF: 2.325, JCR < 30%)
[7] Jung EG, Boo, JH, A numerical study on the heat and mass transfer of a micro heat pipe with a phase-change interface analysis, Heat and Mass Transfer 2017/11, Vol. 53, pp. 3363-3372(SCIE indexed, IF: 2.325, JCR < 30%)
[6] Jung EG, Boo, JH, Improved thermohydraulic numerical model of a heat exchanger for air-to-refrigerant systems, ENERGY 2015/10, Vol. 90, pp. 369-376(SCIE indexed, IF: 8.857, JCR < 5%)
[6] Jung EG, Boo, JH, Improved thermohydraulic numerical model of a heat exchanger for air-to-refrigerant systems, ENERGY 2015/10, Vol. 90, pp. 369-376(SCIE indexed, IF: 8.857, JCR < 5%)
[5] Jung EG, Boo, JH, Thermal numerical model of a high temperature heat pipe heat exchanger under radiation, Applied Energy 2014/12, Vol. 135, pp. 286-596(SCIE indexed, IF: 11.446, JCR < 2%)
[5] Jung EG, Boo, JH, Thermal numerical model of a high temperature heat pipe heat exchanger under radiation, Applied Energy 2014/12, Vol. 135, pp. 286-596(SCIE indexed, IF: 11.446, JCR < 2%)
[4] Jung EG, Boo, JH, Thermal analytical model of latent thermal storage with heat pipe heat exchanger for concentrated solar power, Solar Energy 2014/04, Vol. 102, pp. 318-332(SCIE indexed, IF: 7.188, JCR < 10%)
[4] Jung EG, Boo, JH, Thermal analytical model of latent thermal storage with heat pipe heat exchanger for concentrated solar power, Solar Energy 2014/04, Vol. 102, pp. 318-332(SCIE indexed, IF: 7.188, JCR < 10%)
[3] Jung EG, Boo, JH, Kang HY, Kim NH, Effectiveness of a multi-channel volumetric air receiver for a solar power tower, Heat and Mass Transfer 2013/08, Vol. 49, pp. 1181-1190(SCIE indexed, IF: 2.325, JCR < 30%)
[3] Jung EG, Boo, JH, Kang HY, Kim NH, Effectiveness of a multi-channel volumetric air receiver for a solar power tower, Heat and Mass Transfer 2013/08, Vol. 49, pp. 1181-1190(SCIE indexed, IF: 2.325, JCR < 30%)
[2] Boo JH, Jung EG, Bypass line assisted start-up of a loop heat pipe with a flat evaporator, Journal of Mechanical Science and Technology 2009, Vol. 23, 1613-1619(SCIE indexed, IF: 1.810, JCR < 45%)
[2] Boo JH, Jung EG, Bypass line assisted start-up of a loop heat pipe with a flat evaporator, Journal of Mechanical Science and Technology 2009, Vol. 23, 1613-1619(SCIE indexed, IF: 1.810, JCR < 45%)
[1] Boo JH, Jung EG, Heat Transfer Characteristics of a Loop Heat Pipe with Flat Evaporator Having a Bypass Line, International Mechanical Engineering Congress & Exposition 2006(IMECE2006 ), Vol. 23, 675-680(SCOUPUS indexed,)
[1] Boo JH, Jung EG, Heat Transfer Characteristics of a Loop Heat Pipe with Flat Evaporator Having a Bypass Line, International Mechanical Engineering Congress & Exposition 2006(IMECE2006 ), Vol. 23, 675-680(SCOUPUS indexed,)