Molecular Quantum Heat Engines

HORIZON.1.1HORIZON-ERCID: 101041443
EC Contribution
€17,719
Consortium Size
1 orgs
Summary

Heat engines are an integral part of our daily lives. They power cars or produce electricity by converting heat into work. Increasing their efficiency is very difficult and only marginal improvements have been achieved over the last decades. Thus, to reach the ambitious climate goals, it is necessary to go beyond conventional technologies. Atom-sized systems where quantum mechanical effects come into play could enable this: theory predicts that their efficiency can be boosted beyond the classical limits imposed by thermodynamics. However, so far, this has not been tested in practice due to a lack of suitable model systems.I propose to build a molecular heat engine of only a few atoms in size, with such high control over its structure and properties that these predictions can finally be tested. The engine's quantum properties will be robust at experimentally accessible temperatures, its coupling to the environment will be controllable, and electrical transport through it will be quantum coherent. I seek to exploit the full gamut of their physical properties to boost efficiency, including spin entropy and vibrational coupling. Practically, I will 1) implement a scanning probe setup into a dilution refrigerator, 2) fabricate single-molecule junctions with micro-heaters and ultra-sensitive superconducting thermometers, and 3) perform and interpret caloric experiments on single molecules at unprecedented precision.The results will teach us about the fundamental properties of atom-scale quantum systems and heat flowing through single molecules. It will inspire new ways to increase the performance of thermoelectric applications such as waste heat harvesters, nanoscale spot-cooling devices, or even thermal rectifiers and transistors.I am one of the forerunners in molecular thermoelectrics, with extensive hands-on experience in material sciences, nanotechnology, and mesoscopic physics. This multidisciplinary background is needed to make this ambitious project a success.

Consortium (1)

Project Results (8)

Source: CORDIS, the EU research results database.

Publications (7)
Impact of spin-entropy on the thermoelectric properties of a 2D magnet
Nano Letters· 2024DOI
Alessandra Canetta,[...], Pascal Gehring
Thermoelectric Limitations of Graphene Nanodevices at Ultrahigh Current Densities
ACS Nano· 2024DOI
Charalambos Evangeli, Jacob Swett, Jean Spiece, Edward McCann, Jasper Fried, Achim Harzheim, Andrew R. Lupini, G. Andrew D. Briggs, Pascal Gehring, Stephen Jesse, Oleg V. Kolosov, Jan A. Mol, and Ondrej Dyck
Evidence for intrinsic magnetic scatterers in the topological semimetal (Bi2)5(Bi2Se3)7
APL Materials· 2023DOI
Pascal Gehring ; Clement Merckling ; Ruishen Meng ; Valentin Fonck ; Bart Raes ; Michel Houssa ; Joris Van de Vondel ; Stefan De Gendt
Implementation of SNS thermometers into molecular devices for cryogenic thermoelectric experiments
Applied Physics Letters· 2023DOI
Serhii Volosheniuk, Damian Bouwmeester, Chunwei Hsu, H. S. J. van der Zant, Pascal Gehring
Quantifying the local mechanical properties of twisted double bilayer graphene
Nanoscale· 2023DOI
Alessandra Canetta, Sergio Gonzalez-Munoz, Viet-Hung Nguyen, Khushboo Agarwal, Pauline de Crombrugghe de Picquendaele, Yuanzhuo Hong, Sambit Mohapatra, Kenji Watanabe, Takashi Taniguchi, Bernard Nysten, Benoît Hackens, Rebeca Ribeiro-Palau, Jean-Christoph
Electronic measurements of entropy in meso- and nanoscale systems
Chemical Physics Reviews· 2022DOI
Pyurbeeva, Eugenia and Mol, Jan A. and Gehring, Pascal
Magnetic-Field Universality of the Kondo Effect Revealed by Thermocurrent Spectroscopy
Physical Review Letters· 2022DOI
Hsu, Chunwei and Costi, Theo A. and Vogel, David and Wegeberg, Christina and Mayor, Marcel and van der Zant, Herre S. J. and Gehring, Pascal
Other Results (1)
Periodic Reporting for period 1 - MOUNTAIN (Molecular Quantum Heat Engines)