New carbon phases synthesized under extreme conditions. This project aims to address one of the major fundamental puzzles in carbon science; how to experimentally synthesize new phases of carbon predicted by theory. This could be approached via a combination of high pressure and high-energy ion irradiation to transform novel nano-carbon precursors. The expected outcomes include new phases of carbon with unexplored properties, an understanding of the pathways for synthesis of carbon materials, an ....New carbon phases synthesized under extreme conditions. This project aims to address one of the major fundamental puzzles in carbon science; how to experimentally synthesize new phases of carbon predicted by theory. This could be approached via a combination of high pressure and high-energy ion irradiation to transform novel nano-carbon precursors. The expected outcomes include new phases of carbon with unexplored properties, an understanding of the pathways for synthesis of carbon materials, and new computational tools to understand nano-carbon materials under extreme conditions. This should provide benefits for industries seeking advanced materials for modern manufacturing.Read moreRead less
Giant magnetic-thermoelectricity in topological materials . This project aims to explore magnetic field-induced exotic thermoelectricity in emerging topological materials and develop novel magnetic-field-mediated heat-to-electricity generators and coolers. The significance and outcomes of this project will be the discovery of new magnetic topological materials with thermoelectric conversion efficiency superior to traditional thermoelectric materials and unlocking the physics of the exotic magnet ....Giant magnetic-thermoelectricity in topological materials . This project aims to explore magnetic field-induced exotic thermoelectricity in emerging topological materials and develop novel magnetic-field-mediated heat-to-electricity generators and coolers. The significance and outcomes of this project will be the discovery of new magnetic topological materials with thermoelectric conversion efficiency superior to traditional thermoelectric materials and unlocking the physics of the exotic magnetic-field-correlated thermoelectric phenomena. The outcomes of this project will offer new avenues for novel applications of quantum topological materials and establish a solid foundation for the next generation of thermoelectric devices for various applications.Read moreRead less