Your search keyword '"Jizhou He"' showing total 11 results

1. Optimized finite-time performance of endoreversible quantum Carnot machine working with a squeezed bath

Author

Haoguang Liu, Jizhou He, and Jianhui Wang

Subjects

General Physics and Astronomy

Abstract

We consider a quantum endoreversible Carnot engine cycle and its inverse operation–Carnot refrigeration cycle, working between a hot bath of inverse temperature [Formula: see text] and a cold bath at inverse temperature [Formula: see text]. For the engine model, the hot bath is constructed to be squeezed, whereas for the refrigeration cycle, the cold bath is set to be squeezed. In the high-temperature limit, we analyze efficiency at maximum power and coefficient of performance at maximum figure of merit, revealing the effects of the times allocated to two thermal-contact and two adiabatic processes on the machine performance. We show that, when the total time spent along the two adiabatic processes is negligible, the efficiency at maximum power reaches its upper bound, which can be analytically expressed in terms of squeezing parameter [Formula: see text]: [Formula: see text], with the Carnot efficiency [Formula: see text] and the coefficient of performance at maximum figure of merit is bounded from the upper side by the analytical function: [Formula: see text], where [Formula: see text].

Published

2022

2. Efficiency at maximum power for an Otto engine with ideal feedback.

Author

Honghui Wang, Jizhou He, Jianhui Wang, and Zhaoqi Wu

Subjects

*HEAT engine efficiency, *THERMODYNAMICS of heat engines, *ACTIVATION energy, *MAXWELL'S demon, *NONEQUILIBRIUM statistical mechanics, *CARNOT cycle, *SECOND law of thermodynamics

Abstract

We propose an Otto heat engine that undergoes processes involving a special class of feedback and analyze theoretically its response. We use stochastic thermodynamics to determine the performance characteristics of the heat engine and indicate the possibility that its maximum efficiency can surpass the Carnot value. The analytical expression for efficiency at maximum power, including the effects resulting from feedback, reduces to that previously derived based on an engine without feedback. [ABSTRACT FROM AUTHOR]

Published

2016

3. A theoretical study on the performances of thermoelectric heat engine and refrigerator with two-dimensional electron reservoirs.

Author

Xiaoguang Luo, Jizhou He, Kailin Long, Jun Wang, Nian Liu, and Teng Qiu

Subjects

*HEAT engines, *THERMOELECTRICITY, *ELECTRON transport, *ELECTRONS, *REFRIGERATORS

Abstract

Theoretical thermoelectric nanophysics models of low-dimensional electronic heat engine and refrigerator devices, comprising two-dimensional hot and cold reservoirs and an interconnecting filtered electron transport mechanism have been established. The models were used to numerically simulate and evaluate the thermoelectric performance and energy conversion efficiencies of these low-dimensional devices, based on three different types of electron transport momentum-dependent filters, referred to herein as kx, ky, and kr filters. Assuming the Fermi-Dirac distribution of electrons, expressions for key thermoelectric performance parameters were derived for the resonant transport processes, in which the transmission of electrons has been approximated as a Lorentzian resonance function. Optimizations were carried out and the corresponding optimized design parameters have been determined, including but not limited to the universal theoretical upper bound of the efficiency at maximum power for heat engines, and the maximum coefficient of performance for refrigerators. From the results, it was determined that kr filter delivers the best thermoelectric performance, followed by the kx filter, and then the ky filter. For refrigerators with any one of three filters, an optimum range for the full width at half maximum of the transport resonance was found to be <2kBT. [ABSTRACT FROM AUTHOR]

Published

2014

4. Performance analysis and parametric optimum criteria of an irreversible Bose-Otto engine

Author

Hao Wang, Sanqiu Liu, and Jizhou He

Subjects

Heat-engines -- Evaluation, Thermodynamic cycles -- Analysis, Physics

Abstract

The effects of the irreversibility and the compression ratio of the two isochoric processes on the performance of the Bose-Otto engine and optimization of some important performance parameters are discussed on the basis of the thermodynamic properties of ideal Bose gas. The evaluation and determination of the optimal operating regions including those for the power output, efficiency, and the temperatures of the cyclic working substance at two important state points are also discussed.

Published

2009

5. Quantum boundary effect on the work output of a micro-/nanoscaled Carnot cycle

Author

Nie, Wenjie and Jizhou He

Subjects

Carnot heat engine -- Evaluation, Nanotechnology -- Research, Quantum theory -- Analysis, Physics

Abstract

The quantum boundary effect of gas particles is considered as a working substance of cycle in order to calculate the work output (W) and efficiency ([eta]) of a Carnot cycle in micro-/nanoscale. The studies have shown that under the quantum boundary effect conditions, the work output cycle has depended sensitively on the surface area of the system and is not predicted by the classical approximate result, while the efficiency of cycle is independent of the surface area of the system and equals the Carnot efficiency.

Published

2009

6. A micro-/nanothermosize refrigerator and its performance analysis

Author

Wenjie Nie, Jizhou He, and Xian He

Subjects

Refrigerators -- Design and construction, Thermodynamic processes -- Analysis, Physics

Abstract

The cycle model of a micro-/nanothermosize refrigerator composed of two isothermal and two isobaric processes is described, which is based on the so-called thermosize effects similar to thermoelectric effects. The results have provided theoretical guidance for designing of a micro-/nanoscaled refrigerator.

Published

2008

7. Efficiency at maximum power for an Otto engine with ideal feedback

Author

Jizhou He, Zhaoqi Wu, Jianhui Wang, and Honghui Wang

Subjects

Thermal efficiency, Ideal (set theory), Maximum power principle, General Physics and Astronomy, Thermodynamics, 01 natural sciences, Expression (mathematics), 010305 fluids & plasmas, law.invention, symbols.namesake, Otto engine, law, Control theory, 0103 physical sciences, symbols, Otto cycle, 010306 general physics, Carnot cycle, Heat engine

Abstract

We propose an Otto heat engine that undergoes processes involving a special class of feedback and analyze theoretically its response. We use stochastic thermodynamics to determine the performance characteristics of the heat engine and indicate the possibility that its maximum efficiency can surpass the Carnot value. The analytical expression for efficiency at maximum power, including the effects resulting from feedback, reduces to that previously derived based on an engine without feedback.

Published

2016

8. Optimization on a three-level heat engine working with two noninteracting fermions in a one-dimensional box trap

Author

Jizhou He and Jianhui Wang

Subjects

Physics, Thermal efficiency, General Physics and Astronomy, Thermodynamics, Mechanics, Fermion, symbols.namesake, Thermodynamic cycle, symbols, Adiabatic process, Carnot cycle, Quantum statistical mechanics, Constant (mathematics), Heat engine

Abstract

We setup a three-level heat engine model that works with two noninteracting fermions in a one-dimensional box trap. Besides two quantum adiabatic processes, the quantum heat engine cycle consists of two isoenergetic processes, along which the particles are coupled to energy baths at a high constant energy EH and a low constant energy EC, respectively. Based on the assumption that the potential wall moves at a very slow speed and there exists a heat leakage between two energy baths, we derive the expressions of the power output and the efficiency, and then obtain the optimization region for the heat engine cycle. Finally, we present a brief performance analysis of a Carnot engine between a hot and a cold bath at temperatures TH and TC, respectively. We demonstrate that under the same conditions, the efficiency η=1-(EC/EH) of the engine cycle is bounded from above the Carnot efficiency ηc=1-(TC/TH).

Published

2012

9. Performance analysis and parametric optimum criteria of an irreversible Bose–Otto engine

Author

Sanqiu Liu, Hao Wang, and Jizhou He

Subjects

Chemistry, Isochoric process, General Physics and Astronomy, Thermodynamics, Mechanics, Thermodynamic system, law.invention, Otto engine, law, Thermodynamic cycle, Compression ratio, Otto cycle, Heat engine, Thermodynamic process

Abstract

An irreversible cycle model of a Bose–Otto engine is established, in which finite time thermodynamic processes and the irreversibility result from the nonisentropic compression and expansion processes are taken into account. Based on the model, expressions for the power output and efficiency of the Bose–Otto engine are derived. On the basis of the thermodynamic properties of ideal Bose gas, the effects of the irreversibility and the compression ratio of the two isochoric processes on the performance of the Bose–Otto engine are revealed and some important performance parameters are optimized. Furthermore, some optimal operating regions including those for the power output, efficiency, and the temperatures of the cyclic working substance at two important state points are determined and evaluated. Finally, several special cases are discussed in detail.

Published

2009

10. Quantum boundary effect on the work output of a micro-/nanoscaled Carnot cycle

Author

Jizhou He and Wenjie Nie

Subjects

Physics, symbols.namesake, Work output, Surface-area-to-volume ratio, Isentropic process, Isochoric process, symbols, General Physics and Astronomy, Thermodynamics, Boundary (topology), Function (mathematics), Carnot cycle, Heat engine

Abstract

In this paper, the work output (W) and efficiency (η) of a Carnot cycle in micro-/nanoscale are calculated, in which the quantum boundary effect of gas particles as a working substance of cycle is considered. It is found that under the quantum boundary effect conditions, the work output of cycle depends sensitively on the surface area of the system (boundary of cycle) and cannot be predicted by the classical approximate result (WC), while the efficiency of cycle is independent of the surface area of the system and equals the Carnot efficiency (ηC). Further, the difference of work output of the micro-/nanoscaled Carnot cycle to that of the classical one, ΔW=W−WC, is introduced and can be expressed as the function of the temperature ratio τ=TL/TH of the two heat reservoirs, the volume ratio rV=V3/V1, and the surface area ratio rA=A3/A1 of the two isochoric processes. Variations of difference of work output, ΔW, with the temperature ratio τ and volume ratio rV for the different surface ratio rA are examined,...

Published

2009

11. A micro-/nanothermosize refrigerator and its performance analysis

Author

Jizhou He, Wenjie Nie, and Xian He

Subjects

Materials science, Thermoelectric effect, Refrigerator car, General Physics and Astronomy, Working fluid, Refrigeration, Thermodynamics, Isobaric process, Coefficient of performance, Isothermal process, Ideal gas

Abstract

Based on the so-called thermosize effects similar to thermoelectric effects, the cycle model of a micro-/nanothermosize refrigerator composed of two isothermal and two isobaric processes is established. The working fluid in this cycle consists of atoms in an ideal gas confined in micro-/nanoscale. The detailed expressions for the rate of refrigeration and coefficient of performance are derived in the two cases of reversible and irreversible heat exchanges. Some important performance characteristic curves are plotted. The optimal performance parameters of the micro-/nanothermosize refrigerator are obtained by numerical calculation. The results obtained here will provide theoretical guidance for designing of a micro-/nanoscaled refrigerator.

Published

2008