Your search keyword '"Paolo Andrea Erdman"' showing total 3 results

1. Maximum-power heat engines and refrigerators in the fast-driving regime

Author

Paolo Andrea Erdman, Vasco Cavina, Paolo Abiuso, Vittorio Giovannetti, and Leonardo Tolomeo

Subjects

DYNAMICS, FINITE-TIME, QUANTUM, Maximum power principle, FOS: Physical sciences, Semiclassical physics, Topology, SYSTEMS, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), GENERATORS, Qutrit, Linear combination, Condensed Matter - Statistical Mechanics, THERMODYNAMIC LENGTH, Heat engine, Physics, Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Statistical Mechanics (cond-mat.stat-mech), Power (physics), MODEL, OUTPUT, Thermalisation, Qubit, Otto cycle, ELECTRON, Quantum Physics (quant-ph)

Abstract

We study the optimization of the performance of arbitrary periodically driven thermal machines. Within the assumption of fast modulation of the driving parameters, we derive the optimal cycle that universally maximizes the extracted power of heat engines, the cooling power of refrigerators, and in general any linear combination of the heat currents. We denote this optimal solution as ``generalized Otto cycle'' since it shares the basic structure with the standard Otto cycle, but it is characterized by a greater number of fast strokes. We bound this number in terms of the dimension of the Hilbert space of the system used as working fluid. The generality of these results allows for a widespread range of applications, such as reducing the computational complexity for numerical approaches, or obtaining the explicit form of the optimal protocols when the system-baths interactions are characterized by a single thermalization scale. In this case, we compare the thermodynamic performance of a collection of optimally driven non-interacting and interacting qubits. Remarkably, for refrigerators the non-interacting qubits perform almost as well as the interacting ones, while in the heat engine case there is a many-body advantage both in the maximum power, and in the efficiency at maximum power. Additionally, we illustrate our general results studying the paradigmatic model of a qutrit-based heat engine. Our results strictly hold in the semiclassical case in which no coherence is generated by the driving, and finally we discuss the non-commuting case., Comment: 15+13 pages, 8 figures

Published

2021

2. Fast and accurate Cooper pair pump

Author

Fabio Taddei, Joonas T. Peltonen, Paolo Andrea Erdman, Jukka P. Pekola, Rosario Fazio, Scuola Normale Superiore di Pisa, Consiglio Nazionale delle Ricerche (CNR), Quantum Phenomena and Devices, Centre of Excellence in Quantum Technology, QTF, Department of Applied Physics, Aalto-yliopisto, Aalto University, Erdman, P. A., Taddei, F., Peltonen, J. T., Fazio, R., and Pekola, J. P.

Subjects

Orders of magnitude (temperature), FOS: Physical sciences, Quantum control, QUANTIZED CURRENT, 02 engineering and technology, 01 natural sciences, Superconductivity (cond-mat.supr-con), Charge pumping, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), 0103 physical sciences, SINGLE-ELECTRON TRANSISTOR, 010306 general physics, superconducting circuits, quantum transport, Physics, Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity, Coulomb blockade, 021001 nanoscience & nanotechnology, Computational physics, Modulation, pumping, System parameters, Cooper pair, Quantum Physics (quant-ph), 0210 nano-technology

Abstract

We propose a method to perform accurate and fast charge pumping in superconducting nanocircuits. Combining topological properties and quantum control techniques based on shortcuts to adiabaticity, we show that it is theoretically possible to achieve perfectly quantised charge pumping at any finite-speed driving. Model-specific errors may still arise due the difficulty of implementing the exact control. We thus assess this and other practical issues in a specific system comprised of three Josephson junctions. Using realistic system parameters, we show that our scheme can improve the pumping accuracy of this device by various orders of magnitude. Possible metrological perspectives are discussed., 13 pages, 6 figures

Published

2019

3. Absorption refrigerators based on Coulomb-coupled single-electron systems

Author

Bibek Bhandari, Jukka P. Pekola, Rosario Fazio, Fabio Taddei, Paolo Andrea Erdman, Erdman, P. A., Bhandari, B., Fazio, R., Pekola, J. P., Taddei, F., CNR-ENEA-EURATOM Association, Centre of Excellence in Quantum Technology, QTF, Department of Applied Physics, Aalto-yliopisto, and Aalto University

Subjects

Work (thermodynamics), FOS: Physical sciences, quantum dots, 01 natural sciences, 7. Clean energy, 010305 fluids & plasmas, law.invention, symbols.namesake, law, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), 0103 physical sciences, Coulomb, refrigerator, 010306 general physics, metallic islands, Physics, Condensed Matter - Mesoscale and Nanoscale Physics, ta114, Refrigeration, Observable, Mechanics, Coefficient of performance, Maxwell's demon, Absorption refrigerator, symbols, Carnot cycle

Abstract

We analyze a simple implementation of an absorption refrigerator, a system that requires heat and not work to achieve refrigeration, based on two Coulomb coupled single-electron systems. We analytically determine the general condition to achieve cooling-by-heating, and we determine the system parameters that simultaneously maximize the cooling power and cooling coefficient of performance (COP) finding that the system displays a particularly simple COP that can reach Carnot's upper limit. We also find that the cooling power can be indirectly determined by measuring a charge current. Analyzing the system as an autonomous Maxwell demon, we find that the highest efficiencies for information creation and consumption can be achieved, and we relate the COP to these efficiencies. Finally, we propose two possible experimental setups based on quantum dots or metallic islands that implement the non-trivial cooling condition. Using realistic parameters, we show that these systems, which resemble existing experimental setups, can develop an observable cooling power., 11 pages, 6 figures

Published

2018