We establish quantum thermodynamics for open quantum systems weakly coupled to their reservoirs when the system exhibits degeneracies. The first and second law of thermodynamics are derived, as well as a finite-time fluctuation theorem for mechanical work and energy and matter currents. Using a double quantum dot junction model, local eigenbasis coherences are shown to play a crucial role on thermodynamics and on the electron counting statistics
The first law of thermodynamics imposes not just a constraint on the energy content of systems in ex...
Quantum Thermodynamics is a novel research field which explores the emergence of thermodynamics from...
In this quantum thermodynamics [1] talk, I will discuss work extraction in the quantum regime. We se...
We establish quantum thermodynamics for open quantum systems weakly coupled to their reservoirs when...
Thermodynamics is a highly successful macroscopic theory widely used across the natural sciences and...
Traditional thermodynamics assumes that physical systems live in a probabilistic mixture of energy e...
Planck found, when attempting to describe the way in which hot bodies glow, that energy at microscop...
We investigate manipulations of pure quantum states under incoherent or strictly incoherent operatio...
In thermodynamics, quantum coherences—superpositions between energy eigenstates—behave in distinctly...
Exploiting the relative entropy of coherence, we isolate the coherent contribution in the energetics...
Quantum decoherence is seen as an undesired source of irreversibility that destroys quantum resource...
Quantum energy coherences represent a thermodynamic resource, which can be exploited to extract ener...
We derive from first principles the dynamical equations for the interaction between a heat bath and ...
Quantum coherence is being viewed as a possible resource that could improve the performance of quant...
Quantum coherence can affect the thermodynamics of small quantum systems. Coherences have been shown...
The first law of thermodynamics imposes not just a constraint on the energy content of systems in ex...
Quantum Thermodynamics is a novel research field which explores the emergence of thermodynamics from...
In this quantum thermodynamics [1] talk, I will discuss work extraction in the quantum regime. We se...
We establish quantum thermodynamics for open quantum systems weakly coupled to their reservoirs when...
Thermodynamics is a highly successful macroscopic theory widely used across the natural sciences and...
Traditional thermodynamics assumes that physical systems live in a probabilistic mixture of energy e...
Planck found, when attempting to describe the way in which hot bodies glow, that energy at microscop...
We investigate manipulations of pure quantum states under incoherent or strictly incoherent operatio...
In thermodynamics, quantum coherences—superpositions between energy eigenstates—behave in distinctly...
Exploiting the relative entropy of coherence, we isolate the coherent contribution in the energetics...
Quantum decoherence is seen as an undesired source of irreversibility that destroys quantum resource...
Quantum energy coherences represent a thermodynamic resource, which can be exploited to extract ener...
We derive from first principles the dynamical equations for the interaction between a heat bath and ...
Quantum coherence is being viewed as a possible resource that could improve the performance of quant...
Quantum coherence can affect the thermodynamics of small quantum systems. Coherences have been shown...
The first law of thermodynamics imposes not just a constraint on the energy content of systems in ex...
Quantum Thermodynamics is a novel research field which explores the emergence of thermodynamics from...
In this quantum thermodynamics [1] talk, I will discuss work extraction in the quantum regime. We se...
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