| Thermal energy storage (TES) for industrial waste heat (IWH) recovery: A review L Miró, J Gasia, LF Cabeza Applied energy 179, 284-301, 2016 | 533 | 2016 |
| Experimental evaluation at pilot plant scale of multiple PCMs (cascaded) vs. single PCM configuration for thermal energy storage G Peiró, J Gasia, L Miró, LF Cabeza Renewable energy 83, 729-736, 2015 | 199 | 2015 |
| Review on system and materials requirements for high temperature thermal energy storage. Part 1: General requirements J Gasia, L Miró, LF Cabeza Renewable and Sustainable Energy Reviews 75, 1320-1338, 2017 | 163 | 2017 |
| Experimental evaluation of the use of fins and metal wool as heat transfer enhancement techniques in a latent heat thermal energy storage system J Gasia, JM Maldonado, F Galati, M De Simone, LF Cabeza Energy Conversion and Management 184, 530-538, 2019 | 79 | 2019 |
| Comparative study of the thermal performance of four different shell-and-tube heat exchangers used as latent heat thermal energy storage systems J Gasia, J Diriken, M Bourke, J Van Bael, LF Cabeza Renewable Energy 114, 934-944, 2017 | 75 | 2017 |
| Experimental investigation of the effect of dynamic melting in a cylindrical shell-and-tube heat exchanger using water as PCM J Gasia, NHS Tay, M Belusko, LF Cabeza, F Bruno Applied energy 185, 136-145, 2017 | 75 | 2017 |
| Two-tank molten salts thermal energy storage system for solar power plants at pilot plant scale: Lessons learnt and recommendations for its design, start-up and operation G Peiró, C Prieto, J Gasia, A Jové, L Miró, LF Cabeza Renewable energy 121, 236-248, 2018 | 70 | 2018 |
| Experimental evaluation of a paraffin as phase change material for thermal energy storage in laboratory equipment and in a shell-and-tube heat exchanger J Gasia, L Miró, A De Gracia, C Barreneche, LF Cabeza Applied Sciences 6 (4), 112, 2016 | 68 | 2016 |
| Phase change material selection for thermal processes working under partial load operating conditions in the temperature range between 120 and 200 C J Gasia, M Martin, A Solé, C Barreneche, LF Cabeza Applied Sciences 7 (7), 722, 2017 | 64 | 2017 |
| Process integration of thermal energy storage systems–Evaluation methodology and case studies D Gibb, M Johnson, J Romaní, J Gasia, LF Cabeza, A Seitz Applied energy 230, 750-760, 2018 | 62 | 2018 |
| Materials and system requirements of high temperature thermal energy storage systems: A review. Part 2: Thermal conductivity enhancement techniques J Gasia, L Miró, LF Cabeza Renewable and Sustainable Energy Reviews 60, 1584-1601, 2016 | 62 | 2016 |
| Numerical simulation of a finned-tube LHTES system: influence of the mushy zone constant on the phase change behaviour S Arena, E Casti, J Gasia, LF Cabeza, G Cau Energy Procedia 126, 517-524, 2017 | 58 | 2017 |
| Evaluation of energy density as performance indicator for thermal energy storage at material and system levels J Romaní, J Gasia, A Solé, H Takasu, Y Kato, LF Cabeza Applied energy 235, 954-962, 2019 | 45 | 2019 |
| Use of partial load operating conditions for latent thermal energy storage management J Gasia, A de Gracia, G Peiró, S Arena, G Cau, LF Cabeza Applied energy 216, 234-242, 2018 | 34 | 2018 |
| Numerical analysis of a latent heat thermal energy storage system under partial load operating conditions S Arena, E Casti, J Gasia, LF Cabeza, G Cau Renewable energy 128, 350-361, 2018 | 32 | 2018 |
| Numerical study of dynamic melting enhancement in a latent heat thermal energy storage system J Gasia, D Groulx, NHS Tay, LF Cabeza Journal of Energy Storage 31, 101664, 2020 | 29 | 2020 |
| Evaluation of the state of charge of a solid/liquid phase change material in a thermal energy storage tank G Zsembinszki, C Orozco, J Gasia, T Barz, J Emhofer, LF Cabeza Energies 13 (6), 1425, 2020 | 29 | 2020 |
| IEA SHC Task 42/ECES Annex 29–A simple tool for the economic evaluation of thermal energy storages C Rathgeber, S Hiebler, E Lävemann, P Dolado, A Lazaro, J Gasia, ... Energy Procedia 91, 197-206, 2016 | 29 | 2016 |
| Influence of the storage period between charge and discharge in a latent heat thermal energy storage system working under partial load operating conditions J Gasia, A de Gracia, G Zsembinszki, LF Cabeza Applied energy 235, 1389-1399, 2019 | 28 | 2019 |
| Experimental analysis of charging and discharging processes, with parallel and counter flow arrangements, in a molten salts high temperature pilot plant scale setup G Peiró, J Gasia, L Miró, C Prieto, LF Cabeza Applied energy 178, 394-403, 2016 | 25 | 2016 |
