Physics:Quantum heat engines: Difference between revisions

Scovil and Schulz-DuBois first connected the quantum amplifier to Carnot efficiency in 1959, building a quantum heat engine with a 3-level maser.^[1] Geusic, Schulz-DuBois, De Grasse, and Scovil proposed quantum refrigerators, which pump heat from a cold to a hot reservoir using power, in the same year.^[2] Wineland and Hänsch suggested laser-driven processes, termed optical pumping or laser cooling.^[3][4][5] Alicki reported that heat engines and refrigerators can function at the single-particle scale, necessitating quantum thermodynamics.^[6]

A 3-level amplifier uses hot and cold reservoirs to maintain population inversion between two energy levels, amplifying light via stimulated emission.^[7] The ground level (1-g) and excited level (3-h) connect to a hot reservoir at temperature ${\displaystyle T_{\text{h}}}$, with an energy gap ${\displaystyle \hslash {\omega }_{\text{h}}=E_3-E_1}$. At equilibrium, the population ratio is: $${\displaystyle \frac{N_{\text{h}}}{N_{\text{g}}}=e^{-\frac{\hslash {\omega }_{\text{h}}}{k_{\text{B}}{T}_{\text{h}}}},}$$ where ${\displaystyle \hslash =\frac{h}{2\pi }}$ is the Planck constant, and ${\displaystyle k_{\text{B}}}$ is the Boltzmann constant. A cold reservoir at temperature ${\displaystyle T_{\text{c}}}$ couples the ground level (1-g) to an intermediate level (2-c), with an energy gap ${\displaystyle E_2-E_1=\hslash {\omega }_{\text{c}}}$. At equilibrium: $${\displaystyle \frac{N_{\text{c}}}{N_{\text{g}}}=e^{-\frac{\hslash {\omega }_{\text{c}}}{k_{\text{B}}{T}_{\text{c}}}}.}$$ The device amplifies when levels 3-h and 2-c couple to an external field of frequency ${\displaystyle \nu ={\omega }_{\text{h}}-{\omega }_{\text{c}}}$. Efficiency, defined as the ratio of work output to heat input, is: $${\displaystyle \eta =\frac{\hslash \nu }{\hslash {\omega }_{\text{h}}}=1-\frac{{\omega }_{\text{c}}}{{\omega }_{\text{h}}}.}$$ Amplification requires population inversion: $${\displaystyle G=N_{\text{h}}-N_{\text{c}}\ge 0,}$$ equivalent to: $${\displaystyle \frac{\hslash {\omega }_{\text{c}}}{k_{\text{B}}{T}_{\text{c}}}\ge \frac{\hslash {\omega }_{\text{h}}}{k_{\text{B}}{T}_{\text{h}}}.}$$ This leads to an efficiency limit: $${\displaystyle \eta \le 1-\frac{T_{\text{c}}}{T_{\text{h}}}={\eta }_{\text{c}},}$$ where ${\displaystyle {\eta }_{\text{c}}}$ is the Carnot cycle efficiency, achieved at zero gain (${\displaystyle G=0}$). Reversing the process creates a refrigerator, with a coefficient of performance (COP): $${\displaystyle ϵ=\frac{{\omega }_{\text{c}}}{\nu }\le \frac{T_{\text{c}}}{T_{\text{h}}-T_{\text{c}}}.}$$

Quantum devices operate either continuously or via reciprocating cycles. Continuous devices include solar cells, thermoelectric devices (outputting current), and lasers (outputting coherent light). Continuous refrigerators use optical pumping or laser cooling.^[8][9] Reciprocating devices, such as four-stroke or two-stroke machines, mimic classical engines with non-commuting strokes. Common cycles include the Carnot cycle^[10][11] and Otto cycle.^[12] These cycles yield equations of motion for the working medium and heat flux.

Researchers studied quantum versions of thermodynamic cycles, including the Carnot cycle,[10][11][13] Stirling cycle,[14] and Otto cycle.[12][15] The Otto cycle serves as a model for other reciprocating cycles. File:Q-otto-cycle.pdf The Otto cycle consists of four segments:

• Segment ${\displaystyle A\to B}$: Isomagnetic or isochoric process, partial equilibration with the cold reservoir, described by propagator ${\displaystyle U_{\text{c}}}$.
• Segment ${\displaystyle B\to C}$: Magnetization or adiabatic compression, expanding energy level gaps in the Hamiltonian, described by propagator ${\displaystyle U_{\text{ch}}}$.
• Segment ${\displaystyle C\to D}$: Isomagnetic or isochoric process, partial equilibration with the hot reservoir, described by propagator ${\displaystyle U_{\text{h}}}$.
• Segment ${\displaystyle D\to A}$: Demagnetization or adiabatic expansion, reducing energy gaps, described by propagator ${\displaystyle U_{\text{hc}}}$. The cycle's propagator is: $${\displaystyle U_{\text{global}}=U_{\text{hc}}{U}_{\text{h}}{U}_{\text{ch}}{U}_{\text{c}}.}$$

Propagators are linear operators that define the working medium's state. Consecutive propagators do not commute (${\displaystyle [U_i,U_j]\ne 0}$), ensuring non-zero power. The working medium, such as spin systems^[16] or harmonic oscillators,^[17] requires optimized cycle time. At long cycle times (${\displaystyle {\tau }_{\text{cyc}}\gg 2\pi /\omega }$), the engine operates quasi-adiabatically, with efficiency ${\displaystyle \eta =1-\frac{{\omega }_{\text{c}}}{{\omega }_{\text{h}}}}$, below Carnot efficiency. At high temperatures, efficiency at maximum power is ${\displaystyle \eta =1-\sqrt{\frac{T_{\text{c}}}{T_{\text{h}}}}}$, matching endoreversible thermodynamics.^[17] Short cycle times cause friction-like effects due to non-adiabatic changes, increasing power demands and coherence-induced dissipation. Frictionless solutions exist for finite-time adiabatic expansion/compression.^[18][19] Optimal performance occurs when coherence is minimized. At very short cycle times (${\displaystyle {\tau }_{\text{cyc}}\ll 2\pi /\omega }$), coherence enhances power.^[20] Allahverdyan, Hovhannisyan, and Mahler proposed a two-stroke quantum cycle using two qubits with frequencies ${\displaystyle {\omega }_{\text{h}}}$ and ${\displaystyle {\omega }_{\text{c}}}$. The first stroke partially equilibrates the qubits with hot and cold reservoirs. The second stroke swaps qubit states, preserving entropy and generating power.^[21][22] Quantum Otto cycle refrigerators align with magnetic refrigeration.^[23]

Continuous engines, analogous to turbines, couple to an external periodic field, typically the electromagnetic field, modeling a laser.^[9] Models vary by working medium and heat reservoirs. Studied systems include two-level,^[24] three-level,^[25] four-level,^[26][27] and coupled harmonic oscillators.^[28] Periodic driving splits the energy levels, enabling selective coupling to reservoirs and power production. Ignoring this splitting in equations of motion violates the second law of thermodynamics.^[29] Scully proposed non-thermal fuels, such as coherence or squeezed thermal baths, to increase the hot reservoir's energy without raising entropy, complying with the second law.^[30][31]

Uzdin, Levy, and Kosloff reported that two-stroke, four-stroke, and continuous quantum engines become thermodynamically equivalent in a quantum regime, producing identical work and heat with the same efficiency, driven by coherent work extraction without a classical analogue. Klatzow and others experimentally confirmed these quantum effects.^[32][33]

Elementary quantum heat engines operate near equilibrium, with discrete energy levels as their primary quantum feature. Realistic devices, operating out of equilibrium, experience friction, heat leaks, and finite heat flow. Quantum thermodynamics provides a dynamical framework for such systems. Open quantum system theory describes the working medium's dynamics, tracing out the reservoirs. The total Hamiltonian is: $${\displaystyle H=H_{\text{s}}+H_{\text{c}}+H_{\text{h}}+H_{\text{sc}}+H_{\text{sh}},}$$ where ${\displaystyle H_{\text{s}}(t)}$ is time-dependent. The reduced equation of motion is: $${\displaystyle \frac{d}{dt}\rho =-\frac{i}{\hslash }[H_{\text{s}},\rho ]+L_{\text{h}}(\rho )+L_{\text{c}}(\rho ),}$$ where ${\displaystyle \rho }$ is the density operator, and ${\displaystyle L_{\text{h/c}}}$ represents dissipative dynamics. Energy change is: $${\displaystyle \frac{d}{dt}E=⟨\frac{\partial H_{\text{s}}}{\partial t}⟩+⟨L_{\text{h}}(H_{\text{s}})⟩+⟨L_{\text{c}}(H_{\text{s}})⟩,}$$ yielding the dynamical first law of thermodynamics:^[6] * Power: ${\displaystyle P=⟨\frac{\partial H}{\partial t}⟩}$ * Heat currents: ${\displaystyle J_{\text{h}}=⟨L_{\text{h}}(H_{\text{s}})⟩}$, ${\displaystyle J_{\text{c}}=⟨L_{\text{c}}(H_{\text{s}})⟩}$. Entropy production rate is: $${\displaystyle \frac{dS}{dt}=-\frac{J_{\text{h}}}{T_{\text{h}}}-\frac{J_{\text{c}}}{T_{\text{c}}}\ge 0.}$$ A thermodynamically consistent derivation uses the weak coupling limit, assuming uncorrelated system and reservoirs: $${\displaystyle \rho ={\rho }_{\text{s}}\otimes {\rho }_{\text{h}}\otimes {\rho }_{\text{c}}.}$$ The equation of motion becomes: $${\displaystyle \frac{d}{dt}{\rho }_{\text{s}}=L{\rho }_{\text{s}},}$$ where ${\displaystyle L}$ is the Liouville superoperator, often in the Gorini-Kossakowski-Sudarshan-Lindblad form.^[34] Strong coupling theories also exist.^[35][36][37]

The absorption refrigerator, an autonomous quantum device, requires no external power or intervention.^[38][39][40] It uses three reservoirs: power (

), hot (

), and cold (

).

The tricycle model uses three oscillators:

with resonance condition

. The refrigerator removes excitations from the cold and power reservoirs, generating an excitation in the hot reservoir. The interaction Hamiltonian is:

where

is the coupling strength. Energy balance follows the first law of thermodynamics:

At steady state,

. Entropy production, per the second law of thermodynamics, is:

When

, the power reservoir produces no entropy, yielding pure power:

. Aamir and others implemented this in a superconducting circuit to reset a Qubit.^[41]

Nernst proposed two formulations of the third law of thermodynamics. The Nernst heat theorem states that a pure substance's entropy approaches zero as temperature nears absolute zero. The unattainability principle states that no procedure can cool a system to absolute zero in finite operations.^[42] At steady state, the second law of thermodynamics requires non-negative entropy production. As the cold reservoir approaches absolute zero, entropy production must scale as: $${\displaystyle {\dot{S}}_{\text{c}}\propto -T_{\text{c}}^{\alpha },\alpha \ge 0.}$$The third law strengthens this to ${\displaystyle \alpha >0}$, ensuring zero entropy production at absolute zero (${\displaystyle {\dot{S}}_{\text{c}}=0}$), with heat current scaling as ${\displaystyle J_{\text{c}}\propto T_{\text{c}}^{\alpha +1}}$. The unattainability principle, rephrased by Levy, Alicki, and Kosloff, states that no refrigerator can reach absolute zero in finite time.^[43] Cooling dynamics follow: $${\displaystyle J_{\text{c}}(T_{\text{c}}(t))=-c_V(T_{\text{c}}(t))\frac{d{T}_{\text{c}}(t)}{dt},}$$

where ${\displaystyle c_V(T_{\text{c}})}$ is the reservoir's heat capacity. With ${\displaystyle J_{\text{c}}\propto T_{\text{c}}^{\alpha +1}}$ and ${\displaystyle c_V\sim T_{\text{c}}^{\eta }}$ (${\displaystyle \eta \ge 0}$), the cooling exponent is: $${\displaystyle \frac{d{T}_{\text{c}}(t)}{dt}\propto -T_{\text{c}}^{\zeta },\zeta =\alpha -\eta +1.}$$ If ${\displaystyle \zeta <0}$, cooling to absolute zero in finite time violates the third law, making the unattainability principle more restrictive than the Nernst heat theorem.

Reciprocating devices have been suggested operating by either the Carnot cycle^[10][11] or the Otto cycle.^[12]

In both types the quantum description allows to obtain equation of motion for the working medium and the heat flux.

when the cycle is completed they all turn out to provide the same amount of work and consume the same amount of heat (hence they share the same efficiency as well). This equivalence is associated with a coherent work extraction mechanism and has no classical analogue. These quantum features have been demonstrated experimentally.^[33]

Deffner, Sebastian and Campbell, Steve. "Quantum Thermodynamics: An introduction to the thermodynamics of quantum information", (Morgan & Claypool Publishers, 2019).^[1]

F. Binder, L. A. Correa, C. Gogolin, J. Anders, G. Adesso (eds.) "Thermodynamics in the Quantum Regime. Fundamental Aspects and New Directions." (Springer 2018)

Gemmer, Jochen, M. Michel, and Günter Mahler. "Quantum thermodynamics. Emergence of thermodynamic behavior within composite quantum systems. 2." (2009).

Petruccione, Francesco, and Heinz-Peter Breuer. The theory of open quantum systems. Oxford university press, 2002.

• "Nanoscale heat engine exceeds standard efficiency limit". http://phys.org/news/2014-01-nanoscale-standard-efficiency-limit.html.