SubsidieMeestersExperimental Search for Quantum Advantages in Thermodynamics
This project aims to experimentally explore quantum advantages in thermodynamics using a novel circuit quantum electrodynamics setup to develop and test advanced quantum refrigerators.
Projectdetails
Introduction
The technology advances of the last decades are forcing us to re-think laws and concepts of thermodynamics. An intense theoretical effort is underway to understand the role of quantum mechanical ingredients in thermodynamic processes. This effort might ultimately lead to more powerful engines, less energy waste, and faster-charging batteries.
Challenges in Progress
However, despite pioneering experimental work, progress is hindered by the lack of a comprehensive experimental testbed for quantum thermal machines.
Project Goals
In this project, I aim to provide the most ambitious and systematic experimental search for quantum advantages in thermodynamics thus far, based on a circuit quantum electrodynamics architecture.
Methodology
I will first complement the toolkit of circuit quantum electrodynamics with a novel arrangement, which I term the engineered physical bath. This bath has a broadband, Ohmic spectral density. It can be populated with any spectral distribution and coupled to quantum thermal machines with arbitrary strengths.
Finally, heat flows between the bath and the machine can be detected deep in the quantum regime and in a spectrally resolved way. Based on this augmented architecture, I will implement three types of novel quantum refrigerators:
- Quantum coherence
- Measurement backaction
- Collective effects
I will measure the cooling power of the refrigerators while in situ exploring an unprecedentedly large space of parameters and connect my results to the most recent theoretical frameworks.
Expected Outcomes
From this investigation, I expect two kinds of scientific breakthroughs:
- Observation of features that are unambiguously nonclassical in thermodynamic observables.
- Determination of advantages enjoyed by quantum thermal machines when fairly compared to their classical counterparts.
Conclusion
Broadly, this project will deepen our understanding of quantum thermodynamics while establishing a new standard for experiments in the field.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.124.089 |
| Totale projectbegroting | € 2.124.089 |
Tijdlijn
| Startdatum | 1-1-2023 |
| Einddatum | 31-12-2027 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- CHALMERS TEKNISKA HOGSKOLA ABpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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|---|---|---|---|---|
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Molecular Quantum Heat Engines
The project aims to build a molecular heat engine at the atomic scale to test quantum efficiency predictions, potentially revolutionizing thermoelectric applications and enhancing energy performance.
Entering the deep QuAntum Regimes of NOnequilibrium Thermodynamics
QARNOT aims to extend nonequilibrium thermodynamics into deep quantum regimes using advanced methods to enhance understanding and applications of quantum many-body dynamics and measurements.
Control and complexity in quantum statistical mechanics
This project aims to develop a quantum thermodynamics theory integrating control and measurement effects, while proposing experiments to validate the theoretical framework with existing technologies.
New superconducting quantum-electric device concept utilizing increased anharmonicity, simple structure, and insensitivity to charge and flux noise
ConceptQ aims to develop a novel superconducting qubit with high fidelity and power efficiency, enhancing quantum computing and enabling breakthroughs in various scientific applications.
Engineering QUAntum materials for TErahertz applications
This project aims to leverage the ultrafast thermodynamic properties of quantum materials to develop advanced THz technologies, enhancing performance and capabilities in the terahertz regime.
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Solid-State Cooling Technology for Cryogenic Devices
Developing a compact, fully electrical solid-state refrigerator to achieve sub-kelvin temperatures for advanced electronics and photonics, eliminating the need for 3He and heavy magnets.
SCALABLE MULTI-CHIP QUANTUM ARCHITECTURES ENABLED BY CRYOGENIC WIRELESS / QUANTUM -COHERENT NETWORK-IN PACKAGE
The QUADRATURE project aims to develop scalable quantum computing architectures with distributed quantum cores and integrated wireless links to enhance performance and support diverse quantum algorithms.
Cavity-Integrated Electro-Optics: Measuring, Converting and Manipulating Microwaves with Light
CIELO aims to develop laser-based electro-optic interconnects for scalable quantum processors, enhancing quantum information transfer and enabling advanced sensing applications.