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Journal Abstract Search

248 related items for PubMed ID: 33267490

  • 1. Power, Efficiency and Fluctuations in a Quantum Point Contact as Steady-State Thermoelectric Heat Engine.
    Kheradsoud S, Dashti N, Misiorny M, Potts PP, Splettstoesser J, Samuelsson P.
    Entropy (Basel); 2019 Aug 08; 21(8):. PubMed ID: 33267490
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  • 2. Thermodynamic uncertainty relation in quantum thermoelectric junctions.
    Liu J, Segal D.
    Phys Rev E; 2019 Jun 08; 99(6-1):062141. PubMed ID: 31330645
    [Abstract] [Full Text] [Related]

  • 3. Thermodynamics of the mesoscopic thermoelectric heat engine beyond the linear-response regime.
    Yamamoto K, Hatano N.
    Phys Rev E Stat Nonlin Soft Matter Phys; 2015 Oct 08; 92(4):042165. PubMed ID: 26565226
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  • 4. Thermodynamic Uncertainty Relation in Slowly Driven Quantum Heat Engines.
    Miller HJD, Mohammady MH, Perarnau-Llobet M, Guarnieri G.
    Phys Rev Lett; 2021 May 28; 126(21):210603. PubMed ID: 34114847
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  • 7. Cycling Tames Power Fluctuations near Optimum Efficiency.
    Holubec V, Ryabov A.
    Phys Rev Lett; 2018 Sep 21; 121(12):120601. PubMed ID: 30296120
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  • 9. Non-equilibrium thermoelectric transport across normal metal-quantum dot-superconductor hybrid system within the Coulomb blockade regime.
    Verma S, Singh A.
    J Phys Condens Matter; 2022 Feb 07; 34(15):. PubMed ID: 35045407
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  • 10. A quantum-dot heat engine operating close to the thermodynamic efficiency limits.
    Josefsson M, Svilans A, Burke AM, Hoffmann EA, Fahlvik S, Thelander C, Leijnse M, Linke H.
    Nat Nanotechnol; 2018 Oct 07; 13(10):920-924. PubMed ID: 30013221
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  • 12. Most efficient quantum thermoelectric at finite power output.
    Whitney RS.
    Phys Rev Lett; 2014 Apr 04; 112(13):130601. PubMed ID: 24745399
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  • 14. Finite-time performance of a quantum heat engine with a squeezed thermal bath.
    Wang J, He J, Ma Y.
    Phys Rev E; 2019 Nov 04; 100(5-1):052126. PubMed ID: 31870038
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