It is investigated whether non-Markovianity, i.e., the memory effects resulting from the coupling of the system to its environment, can be beneficial for the performance of quantum heat engines. Specifically, two physical models are considered. The first one is a well known single-qubit Otto engine; the non-Markovian behaviour is there implemented by replacing standard thermalization strokes with so-called extremal thermal operations which cannot be realized without the memory effects. The second one is a three-stroke engine in which the cycle consists of two extremal thermal operations and a single qubit rotation. It is shown that the non-Markovian Otto engine can generate more work-per-cycle for a given efficiency than its Markovian count...
At the heart of quantum thermodynamics lies a fundamental question about what is genuine "quantum" i...
We introduce a generalized approach to characterize the non-Markovianity of quantum dynamical maps v...
Quantization of energy is a quintessential characteristic of quantum systems. Here we analyze its ef...
In the quest for high-performance quantum thermal machines, looking for an optimal thermodynamic eff...
We study a minimal quantum Otto heat engine, where the working medium consists of an interacting few...
The performance of quantum heat engines is generally based on the analysis of a single cycle. We cha...
Understanding heat transfer between a quantum system and its environment is of undisputed importance...
We investigate the limits on cooling and work extraction via Markovian thermal processes assisted by...
In a quantum Stirling heat engine, the heat exchanged with two thermal baths is partly utilized for ...
Recent predictions for quantum-mechanical enhancements in the operation of small heat engines have r...
Fluctuations strongly affect the dynamics and functionality of nanoscale thermal machines. Recent de...
Heat engines usually operate by exchanging heat with thermal baths at different (positive) temperatu...
We study the thermodynamic performance of a finite-time non-regenerative quantum Stirling-like cycle...
Algebraic methods for solving time dependent Hamiltonians are used to investigate the performance of...
Generalized measurements may allow the control of its back-action on the quantum system by interpola...
At the heart of quantum thermodynamics lies a fundamental question about what is genuine "quantum" i...
We introduce a generalized approach to characterize the non-Markovianity of quantum dynamical maps v...
Quantization of energy is a quintessential characteristic of quantum systems. Here we analyze its ef...
In the quest for high-performance quantum thermal machines, looking for an optimal thermodynamic eff...
We study a minimal quantum Otto heat engine, where the working medium consists of an interacting few...
The performance of quantum heat engines is generally based on the analysis of a single cycle. We cha...
Understanding heat transfer between a quantum system and its environment is of undisputed importance...
We investigate the limits on cooling and work extraction via Markovian thermal processes assisted by...
In a quantum Stirling heat engine, the heat exchanged with two thermal baths is partly utilized for ...
Recent predictions for quantum-mechanical enhancements in the operation of small heat engines have r...
Fluctuations strongly affect the dynamics and functionality of nanoscale thermal machines. Recent de...
Heat engines usually operate by exchanging heat with thermal baths at different (positive) temperatu...
We study the thermodynamic performance of a finite-time non-regenerative quantum Stirling-like cycle...
Algebraic methods for solving time dependent Hamiltonians are used to investigate the performance of...
Generalized measurements may allow the control of its back-action on the quantum system by interpola...
At the heart of quantum thermodynamics lies a fundamental question about what is genuine "quantum" i...
We introduce a generalized approach to characterize the non-Markovianity of quantum dynamical maps v...
Quantization of energy is a quintessential characteristic of quantum systems. Here we analyze its ef...