Adamson K-MWalmsley TGCarson JKChen QSchlosser FKong LCleland DJ2023-10-152023-11-032022-08-122023-10-152023-11-032022-10Adamson KM, Walmsley TG, Carson JK, Chen Q, Schlosser F, Kong L, Cleland DJ. (2022). High-temperature and transcritical heat pump cycles and advancements: A review. Renewable and Sustainable Energy Reviews. 167.1364-0321https://mro.massey.ac.nz/handle/10179/69005Industrial and large-scale heat pumps are a well-established, clean and low-emission technology for processing temperatures below 100 °C, especially when powered by renewable energy. The next frontier in heat pumping is to extend the economic operating envelope to supply the 100–200 °C range, where an estimated 27% of industrial process heat demand is required. Most high-temperature heat pump cycles operate at pressures below the refrigerant's critical point. However, high-temperature transcritical heat pump (HTTHP) technology has - due to the temperature glide – a significant efficiency potential, especially for processes with large temperature changes on the sink side. This review examines how further developments in HTTHP technology can leverage innovations from high-temperature heat pump research to respond to key technical challenges. To this end, a comprehensive list of 49 different high temperature or transcritical heat pump cycle structures was compiled, which lead to classification of 10 performance-enhancing cycle components. Focusing specifically on high-temperature transcritical heat pump cycles, this review establishes six technical challenges facing their development and proposes solutions for each challenge, including a new transcritical-transcritical cascade cycle innovation. A key outcome of the review is the proposal of a new cycle that requires detailed investigation as a candidate for a high-temperature transcritical heat pump cycle.(c) The author/s CC BYhttps://creativecommons.org/licenses/by/4.0/High-temperature heat pumpTranscritical heat pumpVapour compression cycleProcess integrationJournal article10.1016/j.rser.2022.1127981879-06902023-10-13journal-article