Your search keyword '"Jizhou, He"' showing total 130 results

101. Heat-Transfer Effect on the Performance of a Magnetic Ericsson Refrigerator

Author

Jincan Chen, Jizhou He, and Chih Wu

Subjects

Materials science, Nuclear engineering, Heat transfer, Refrigerator car, General Physics and Astronomy, General Chemistry

Published

2002

102. A NANOTHERMOELECTRIC HEAT ENGINE WORKING WITH TWO-LEVEL QUANTUM SYSTEM

Author

Yuling Xiao, Yan-Chao Zhang, Hong-Ni Liang, and Jizhou He

Subjects

Physics, Master equation, Quantum system, Thermodynamics, Statistical and Nonlinear Physics, Power output, Mechanics, Condensed Matter Physics, Energy (signal processing), Heat engine

Abstract

In this paper, we establish a nanothermoelectric engine consisting of two discrete energy levels embedded between two reservoirs at different temperatures and chemical potentials. Based on master equation, the expressions for the power output and efficiency of the nanothermoelectric engine are derived. The characteristic curves between the power output and the efficiency are plotted. Moreover, the optimal performance parameters are obtained by the numerical calculation. The influence of the strength of variations in electron–electron interactions on the optimal performance parameters is analyzed in detail.

Published

2014

103. Quantum refrigeration cycles using spin-1/2 systems as the working substance

Author

Jizhou, He, Jincan, Chen, and Ben, Hua

Abstract

The cycle model of a quantum refrigerator composed of two isothermal and two isomagnetic field processes is established. The working substance in the cycle consists of many noninteracting spin-1/2 systems. The performance of the cycle is investigated, based on the quantum master equation and semigroup approach. The general expressions of several important performance parameters, such as the coefficient of performance, cooling rate, and power input, are given. Especially, the case at high temperatures is analyzed in detail. The results obtained are further generalized and discussed, so that they may be directly used to describe the performance of the quantum refrigerator using spin-J systems as the working substance. Finally, the optimum characteristics of the quantum Carnot refrigerator are derived simply.

Published

2001

104. Performance characteristics and optimal analysis of an interacting quantum dot thermoelectric refrigerator

Author

Jizhou He, Yan-Chao Zhang, Yuling Xiao, and Xian He

Subjects

Physics, Work (thermodynamics), Thermoelectric cooling, Condensed matter physics, Refrigerator car, Mechanics, Electron, Coefficient of performance, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Quantum dot, Quantum master equation, Coulomb, Mathematical Physics

Abstract

We investigate the thermodynamic performance of a quantum-dot refrigerator consisting of a single orbital interacting quantum dot embedded between two electron reservoirs at different temperatures and chemical potentials. Based on the quantum master equation the expressions for the cooling power and the coefficient of performance are derived. The characteristic curves between the cooling power and the coefficient of performance are plotted, and the optimal regions of the performance parameters are determined. Moreover, the optimal performance parameters are calculated numerically. Finally, the influence of the Coulomb interaction and the temperature ratio on optimal performance parameters are discussed in detail. The results obtained here can provide some theoretical guidelines for the design and operation of the practical quantum-dot refrigerator. Our work is not restricted to the linear-response regime.

Published

2013

105. 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

106. Performance characteristics of a micro-Brownian refrigerator in a one-dimensional lattice

Author

Xiaoxia Qian, Yanping Zhang, Hong Ouyang, and Jizhou He

Subjects

Physics, Refrigerator car, Thermodynamics, Mechanics, Coefficient of performance, Condensed Matter Physics, Potential energy, Atomic and Molecular Physics, and Optics, symbols.namesake, Heat flux, Master equation, symbols, Carnot cycle, Mathematical Physics, Brownian motion, Quasistatic process

Abstract

Particle hopping on a one-dimensional lattice driven by an external force in a periodic sawtooth potential and temperature field may act as a micro-Brownian refrigerator. In order to clarify the underlying physical pictures of the refrigerator, heat flows via both the potential energy and the kinetic energy of the particle are considered simultaneously. Based on the master equation describing the jump of the particle among the three states, expressions for the cooling rate and the coefficient of performance of the refrigerator are derived analytically. The general performance characteristic curves are plotted by numerical calculation. It is found that the characteristic curve between the cooling rate and the coefficient of performance is a loop-shaped one; the Brownian refrigerator is irreversible and its coefficient of performance is always less than the Carnot value. The influence of the temperature ratio of the heat reservoirs and the height of the sawtooth potential on the optimal performance characteristic parameters is analyzed. When heat flow via the kinetic energy of the particle is neglected, the characteristic curve between the cooling rate and the coefficient of performance is an open-shaped one. In this case, the Brownian refrigerator is reversible and its coefficient of performance reaches the Carnot value in the quasistatic limit.

Published

2010

107. Local stability analysis of an endoreversible Carnot refrigerator

Author

Jizhou He, Wenjie Nie, and Guiling Miao

Subjects

Physics, Refrigerator car, Thermodynamics, Coefficient of performance, Condensed Matter Physics, Heat capacity, Atomic and Molecular Physics, and Optics, Isothermal process, symbols.namesake, Thermal conductivity, Linearization, symbols, Working fluid, Carnot cycle, Mathematical Physics

Abstract

A local stability analysis of an endoreversible Carnot refrigerator, working at the maximum objective function of the product of the cooling rate R and the coefficient of performance e, is presented. The endoreversible Carnot refrigerator consists of a reversible Carnot refrigerator that exchanges heat with the heat reservoirs TH through the thermal conductance α and with the cold reservoirs TL through the thermal conductance β. In addition, the working fluid has the same heat capacity C in the two isothermal branches of the cycle. By linearization and stability analysis, we find that the relaxation times are a function of α, β, the heat capacity C and τ=TL /TH; that the endoreversible Carnot refrigerator is stable for every value of α, β, C and τ; that after a perturbation, the system state exponentially decays to the steady state with either of two different relaxation times; that both relaxation times are proportional to α/2C; and that one of them is a monotonically increasing function τ and the other is almost independent of τ. Finally, the phase portraits for the trajectories after a small perturbation over the steady-state values of internal temperatures are presented.

Published

2010

108. Optimum performance analysis of an energy selective electron refrigerator affected by heat leaks

Author

Xiaomin Wang, Jizhou He, and Hongni Liang

Subjects

Materials science, Phonon, Refrigerator car, Resonance, Thermodynamics, Mechanics, Electron, Coefficient of performance, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Power (physics), Heat flux, Mathematical Physics, Energy (signal processing)

Abstract

An energy selective electron (ESE) refrigerator with heat leaks is established in a one-dimensional system. Based on the theory of electronic transport, the expressions of the heat flux into hot and cold electron reservoirs are derived. When the heat leaks between two electron reservoirs via phonons are taken into account, the cooling rate, coefficient of performance (COP) and input power are obtained. The performance characteristic curves such as the cooling rate versus the COP, the cooling rate and the COP versus the center position of the resonance energy level are plotted by numerical calculation. The influence of the center position and width of the resonance energy level on the performance of the ESE refrigerator is analyzed in detail. Lastly, the influence of heat leaks and average temperature on the performance of the ESE refrigerator is discussed. The results obtained here have theoretical significance for understanding the thermodynamic performance of the practical ESE refrigerator.

Published

2009

109. 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

110. 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

111. 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

112. Ecological performance optimization analysis of a new irreversible quantum harmonic heat engine.

Author

Xian He, Jizhou He, and Yuling Xiao

Published

2011

113. Effect of Multi-Irreversibilities on the Performance Characteristics of an Irreversible Air-Standard Diesel Heat Engine.

Author

Jizhou He and Junbin Li

Published

2010

114. Performance Characteristics and Optimal Analysis of an Energy Selective Electron Refrigerator.

Author

Cong Li, Ruiwen Li, Xiaoguang Luo, Li Ma, and Jizhou He

Subjects

ELECTRON transport, REFRIGERATORS, ELECTRIC filters, TEMPERATURE effect, COOLING, NUMERICAL calculations

Abstract

In this paper, the energy selective electron (ESE) refrigerator with an ideal energy filter based on resonant tunneling is established. It consists of two infinitely large electron reservoirs with different temperatures and chemical potentials, and electrons can be exchanged between the two reservoirs through the ideal energy filter. According to Landauer formula and the assumption of being coupled tightly with the electron current, the expressions for the heat flux, the cooling rate and the coefficient of performance (COP) are derived analytically. The performance characteristic curves such as the cooling rate versus coefficient of performance, the cooling rate and coefficient of performance versus the position of energy level are plotted by numerical calculation. The optimal regions of the cooling rate and the COP are determined. Moreover, we optimize the cooling rate and the COP respectively with respect to the position of energy level. The influence of the width of energy level on performance of the ESE refrigerator is discussed. Finally, based on the optimization criterion χ = γ ⋅ ...C for refrigerator, i.e. the product of the COP times the cooling rate, the optimal performance of the ESE refrigerator is discussed in detail. [ABSTRACT FROM AUTHOR]

Published

2014

115. Performance characteristics and optimal analysis of an interacting quantum dot thermoelectric refrigerator.

Author

Yanchao Zhang, Jizhou He, Xian He, and Yuling Xiao

Published

2013

116. Efficiency at maximum power output of an irreversible Carnot-like cycle with internally dissipative friction.

Author

Jianhui Wang and Jizhou He

Subjects

*MAXIMUM power transfer theorem, *FRICTION, *HEAT engines, *ISOTHERMAL processes, *HYPERBOLIC processes, *STOCHASTIC processes

Abstract

We investigate the efficiency at the maximum power output (EMP) of an irreversible Carnot engine performing finite-time cycles between two reservoirs at constant temperatures Th, and Tc (

Published

2012

117. Efficiency at maximum power output of quantum heat engines under finite-time operation.

Author

Jianhui Wang, Jizhou He, and Zhaoqi Wu

Subjects

*QUANTUM theory, *HEAT engines, *ADIABATIC engines, *ENERGY dissipation, *SYMMETRY (Physics), *WATER temperature, *CARNOT cycle, *MECHANICAL efficiency, *ELECTRIC power production

Abstract

We study the efficiency at maximum power, &eegr;m, of irreversible quantum Camot engines (QCEs) that perform finite-time cycles between a hot and a cold reservoir at temperatures Th and Tc., respectively. For QCEs in the reversible limit (long cycle period, zero dissipation), &eegr;m becomes identical to the Carnot efficiency &eegr;c = 1 -- Tc/Th- For QCE cycles in which nonadiabatic dissipation and the time spent on two adiabais are included, the efficiency &eegr;m at maximum power output is bounded from above by &eegr;c/(2 -- &eegr;c) and from below by &eegr;c/2. In the case of symmetric dissipation, the Curzon-Ahlbom efficiency &eegr;CA = 1 - √Tc/Th is recovered under the condition that the time allocation between the adiabais and the contact time with the reservoir satisfy a certain relation. [ABSTRACT FROM AUTHOR]

Published

2012

118. Performance analysis of a two-state quantum heat engine working with a single-mode radiation field in a cavity.

Author

Jianhui Wang, Jizhou He, and Xian He

Subjects

*QUANTUM efficiency, *THERMODYNAMICS, *ADIABATIC flow, *HEAT engineering, *RADIATION, *CAVITY resonators

Abstract

We present a performance analysis of a two-state heat engine model working with a single-mode radiation field in a cavity. The heat engine cycle consists of two adiabatic and two isoenergetic processes. Assuming the wall of the potential moves at a very slow speed, we determine the optimization region and the positive work condition of the heat engine model. Furthermore, we generalize the results to the performance optimization for a two-state heat engine with a one-dimensional power-law potential. Based on the generalized model with an arbitrary one-dimensional potential, we obtain the expression of efficiency as η = 1 - EC/EH, with EH (EC) denoting the expectation value of the system Hamiltonian along the isoenergetic process at high (low) energy. This expression is an analog of the classical thermodynamical result of Carnot, ηc = 1 - TC/TH, with TH (TC) being the temperature along the isothermal process at high (low) temperature. We prove that under the same conditions, the efficiency η = 1 - EC/EH is bounded from above the Carnot efficiency, ηc = 1 - TC/TH, and even quantum dynamics is reversible. [ABSTRACT FROM AUTHOR]

Published

2011

119. Condensate fluctuations of interacting Bose gases within a microcanonical ensemble.

Author

Jianhui Wang, Jizhou He, and Yongli Ma

Subjects

*BOSE-Einstein condensation, *BOSE-Einstein gas, *FLUCTUATIONS (Physics), *FINITE element method, *PARTICLES (Nuclear physics)

Abstract

Based on counting statistics and Bogoliubov theory, we present a recurrence relation for the microcanonical partition function for a wealdy interacting Bose gas with a finite number of particles in a cubic box. According to this microcanonical partition function, we calculate numerically the distribution function, condensate fraction, and condensate fluctuations for a finite and isolated Bose-Einstein condensate. For ideal and weakly interacting Bose gases, we compare the condensate fluctuations with those in the canonical ensemble. The present approach yields an accurate account of the condensate fluctuations for temperatures close to the critical region. We emphasize that the interactions between excited atoms turn out to be important for moderate temperatures. [ABSTRACT FROM AUTHOR]

Published

2011

120. Optimization on the Performance Characteristics of a Magnetic Ericsson Refrigeration Cycle Affected by Multi-Irreversibilities.

Author

Jizhou He, Jincan Chen, and Chih Wu

Subjects

*REFRIGERATION & refrigerating machinery, *ERICSSON cycle, *HEAT transfer, *MAGNETISM, *THERMODYNAMICS, *COOLING

Abstract

A general irreversible cycle model of a magnetic Ericsson refrigerator is established. The irreversibilities in the cycle model result from the finite-rate heat transfer between the working substance and the external heat reservoirs, the inherent regenerative loss, the additional regenerative loss due to thermal resistances, and the heat leak loss between the external heat reservoirs. The cycle model is used to optimize the performance of the magnetic Ericsson refrigeration cycle. The fundamental optimum relation between the cooling rate and the coefficient of performance of the cycle is derived. The maximum coefficient of performance, maximum cooling rate and other relevant important parameters are calculated. The optimal operating region of the cycle is determined. The results obtained here are very general and will be helpful for the optimal design and operation of the magnetic Ericsson refrigerators. [ABSTRACT FROM AUTHOR]

Published

2003

121. Heat-Transfer Effect on the Performance of a Magnetic Ericsson Refrigerator.

Author

Jizhou He, Jincan Chen, and Chih Wu

Subjects

*HEAT transfer, *COOLING, *HEAT radiation & absorption, *REFRIGERATORS, *REFRIGERATION & refrigerating machinery

Abstract

The irreversibilities resulting from the finite-rate heat transfer between the working substance and the external heat reservoirs and the regenerative losses in regenerative processes are considered in the cycle model of a magnetic Ericsson refrigerator. The fundamental optimum relations between the cooling rate and the coefficient of performance and between the power input and the coefficient of performance are derived, based on a class of heat-transfer laws and the Curie law. The general characteristic curves of the cycle are presented. The effect of the different forms of the regenerative time and heat-transfer laws on the performance of the cycle is discussed in detail. The results obtained here will be useful to further understand the general optimum performance of real magnetic Ericsson refrigerators. [ABSTRACT FROM AUTHOR]

Published

2002

122. Power, Efficiency and Ecological Optimization for an Irreversible Braysson Heat Engine.

Author

Jizhou He, Xian He, and Bei Yang

Published

2011

123. Finite-power performance of quantum heat engines in linear response.

Author

Qin Liu, Jizhou He, Yongli Ma, and Jianhui Wang

Subjects

*HEAT engines, *QUANTUM thermodynamics, *BRAYTON cycle, *CARNOT cycle, *ADIABATIC processes, *LINEAR orderings

Abstract

We investigate the finite-power performance of quantum heat engines working in the linear response regime where the temperature gradient is small. The engine cycles with working substances of ideal harmonic systems consist of two heat transfer and two adiabatic processes, such as the Carnot cycle, Otto cycle, and Brayton cycle. By analyzing the optimal protocol under maximum power we derive the explicitly analytic expression for the irreversible entropy production, which becomes the low dissipation form in the long duration limit. Assuming the engine to be endoreversible, we derive the universal expression for the efficiency at maximum power, which agrees well with that obtained from the phenomenological heat transfer laws holding in the classical thermodynamics. Through appropriate identification of the thermodynamic fluxes and forces that a linear relation connects, we find that the quantum engines under consideration are tightly coupled, and the universality of efficiency at maximum power is confirmed at the linear order in the temperature gradient. [ABSTRACT FROM AUTHOR]

Published

2019

124. Efficiency at maximum power of a quantum Otto cycle within finite-time or irreversible thermodynamics.

Author

Feilong Wu, Jizhou He, Yongli Ma, and Jianhui Wang

Subjects

*OTTO cycle, *THERMODYNAMIC cycles, *THERMODYNAMICS, *QUANTUM statistics, *PARTICLE statistics (Statistical physics)

Abstract

We consider the efficiency at maximum power of a quantum Otto engine, which uses a spin or a harmonic system as its working substance and works between two heat reservoirs at constant temperatures Th and Tc (

Published

2014

125. Coefficient of performance under maximum χ criterion in a two-level atomic system as a refrigerator.

Author

Yuan Yuan, Rui Wang, Jizhou He, Yongli Ma, and Jianhui Wang

Subjects

*REFRIGERATORS, *QUANTUM thermodynamics, *ATOMIC physics, *ADIABATIC processes, *ISOCHORIC processes

Abstract

A two-level atomic system as a working substance is used to set up a refrigerator consisting of two quantum adiabatic and two isochoric processes (two constant-frequency processes ωa and ωb with ωa < ωb), during which the two-level system is in contact with two heat reservoirs at temperatures Th, and Tc(

Published

2014

126. Efficiency at maximum power of a heat engine working with a two-level atomic system.

Author

Rui Wang, Jianhui Wang, Jizhou He, and Yongli Ma

Subjects

*HEAT engines, *ENERGY consumption, *ENERGY levels (Quantum mechanics), *QUANTUM theory, *ENERGY dissipation, *FRICTION, *ADIABATIC processes

Abstract

We consider the finite-time operation of a quantum heat engine whose working substance is composed of a two-level atomic system. The engine cycle, consisting of two quantum adiabatic and two quantum isochoric (constant-frequency) processes and working between two heat reservoirs at temperatures Th and Tc(

Published

2013

127. Performance of a multilevel quantum heat engine of an ideal N-particle Fermi system.

Author

Rui Wang, Jianhui Wang, Jizhou He, and Yongli Ma

Subjects

*QUANTUM theory, *HEAT engines, *PERFORMANCE evaluation, *PARTICLES (Nuclear physics), *ELECTRON gas, *MATHEMATICAL models, *POTENTIAL theory (Physics)

Abstract

We generalize the quantum heat engine (QHE) model which was first proposed by Bender et al. [J. Phys. A 33, 4427 (2000)] to the case in which an ideal Fermi gas with an arbitrary number N of particles in a box trap is used as the working substance. Besides two quantum adiabatic processes, the engine model contains two isoenergetic processes, during which the particles are coupled to energy baths at a high constant energy Eh and a low constant energy Ec, respectively. Directly employing the finite-time thermodynamics, we find that the power output is enhanced by increasing particle number N (or decreasing minimum trap size LA) for given LA (or N), without reduction in the efficiency. By use of global optimization, the efficiency at possible maximum power output (EPMP) is found to be universal and independent of any parameter contained in the engine model. For an engine model with any particle-number N, the efficiency at maximum power output (EMP) can be determined under the condition that it should be closest to the EPMP. Moreover, we extend the heat engine to a more general multilevel engine model with an arbitrary ID power-law potential. Comparison between our engine model and the Carnot cycle shows that, under the same conditions, the efficiency η = 1 -- Ec&frac;Eh of the engine cycle is bounded from above the Carnot value ηc = 1 -- Tc&frac;Th. [ABSTRACT FROM AUTHOR]

Published

2012

128. Quantum Otto engine of a two-level atom with single-mode fields.

Author

Jianhui Wang, Zhaoqi Wu, and Jizhou He

Subjects

*QUANTUM theory, *WORKING substances, *ADIABATIC processes, *PERFORMANCE evaluation, *HEAT engines, *MATHEMATICAL models

Abstract

We establish a quantum Otto engine (QOE) of a two-level atom, which is confined in a one-dimensional (ID) harmonic trap and is coupled to single-mode radiation fields. Besides two adiabatic processes, the QOE cycle consists of two isochoric processes, along one of which the two-level atom as the working substance interacts with a single-mode radiation field. Based on the semigroup approach, we derive the time for completing any adiabatic process and then present a performance analysis of the heat engine model. Furthermore, we generalize the results to the performance optimization for a QOE of a single two-level atom trapped in a 1D power-law potential. Our result shows that the efficiency at maximum power output is dependent on the trap exponent 9 but is independent of the energy spectrum index &sgr;. [ABSTRACT FROM AUTHOR]

Published

2012

129. Four-level refrigerator driven by photons.

Author

Jianhui Wang, Yiming Lai, Zhuolin Ye, Jizhou He, Yongli Ma, and Qinghong Liao

Subjects

*ABSORPTIVE refrigeration, *PHOTONS, *QUANTUM theory, *COEFFICIENTS (Statistics), *SOLAR heating, *THERMODYNAMICS, *COOLING

Abstract

We propose a quantum absorption refrigerator driven by photons. The model uses a four-level system as its working substance and couples simultaneously to hot, cold, and solar heat reservoirs. Explicit expressions for the cooling power Qc, and coefficient of performance (COP)ηcop are derived, with the purpose of revealing and optimizing the performance of the device. Our model runs most efficiently under the tight coupling condition, and it is consistent with the third law of thermodynamics in the limit T → 0. [ABSTRACT FROM AUTHOR]

Published

2015

130. Performance characteristics and optimal analysis of a nanosized quantum dot photoelectric refrigerator.

Author

Cong Li, Yanchao Zhang, Jianhui Wang, and Jizhou He

Subjects

*NANOPARTICLES, *QUANTUM dots, *PHOTOELECTRICITY, *REFRIGERATORS, *THERMODYNAMIC equilibrium, *ENERGY levels (Quantum mechanics), *COOLING

Abstract

We study the thermodynamic performance of a nanosized photoelectric refrigerator consisting of three coupled single-level quantum dots embedded between two reservoirs at different temperatures. Based on the quantum master equation, we derive expressions for the cooling power and coefficient of performance (COP) of the refrigerator and plot the characteristic curves between the cooling power and the COP. We analyze the optimal performance parameters under conditions of maximum cooling power and maximum COP, and we discuss the influence of the energy level difference and the temperature ratio on the optimal performance parameters in detail. [ABSTRACT FROM AUTHOR]

Published

2013