The emergence of quantum information science and the subsequent development of quantum technologies is firmly rooted in the newly found appreciation of physical properties such as coherent superposition, entanglement and entropy as resources. These resources provide the fuel for quantum technologies that enables them to achieve efficiencies beyond the limits imposed by classical physics. The optimal exploitation of resources in quantum technologies requires as a foundation both a firm mathematical framework for a rigorous characterisation, manipulation and verification of quantum resources and experimental technologies that can manipulate them in practice. Building on these foundations, jointly theory and experiment can then design and realise protocols and devices to deliver optimised quantum technologies.To this end, ExTRaQT will:i) Develop the mathematical foundations of resource theories for states, operations and dynamics and apply them specifically to the resources of coherence and to thermodynamic processes at the quantum scale. Key processes in these resource theories will be identified to use them as a basis on which to achieve their experimental realisation.ii) Design theoretically and optimise numerically experimental designs of key resource manipulation processes and quantum scale heat engines based on realistic parameters of the experimental platforms of trapped ions and of bio-molecular systems.iii) Use trapped ion quantum technologies to realise atomic scale quantum heat engines in contact with classical and quantum heat baths and analyse their performance in terms of the resource theory of quantum thermodynamics. Design and realise a quantum simulator for open quantum systems in contact with structured reservoirs capable of emulating dynamics of bio-molecular systems.iv) Observe coherent electron-vibrational quantum transport dynamics in bio-molecular systems, assess the role of coherent dynamics and analyse these dynamics in terms of quantum heat engines. Electronic and vibrational structure of those systems will be tailored to achieve control over thermodynamic processes in such systems.Individually, members of ExTRaQT have made fundamental contributions to all aspects of the project theme. In ExTRaQT, for the first time, they will form an integrated interdisciplinary collaboration to develop resource theories, apply them experimentally for enhanced quantum technologies as well as study of quantum dynamics in biological systems.

DFG Programme Research Grants

International Connection France, Poland, Spain

Co-Investigators Professorin Dr. Susana Huelga; Professor Dr. Daqing Wang

Cooperation Partners Professor Dr. Michal Horodecki; Professor Dr. Niek F. van Hulst; Dr. Alexander Streltsov; Professor Dr. Andreas Winter