Laser and photocell quantum heat engines (QHEs) are powered by thermal light and governed by the laws of quantum thermodynamics. To appreciate the deep connection between quantum mechanics and thermodynamics we need only recall that in 1901 Planck introduced the quantum of action to calculate the entropy of thermal light, and in 1905 Einstein’s studies of the entropy of thermal light led him to introduce the photon. Then in 1917, he discovered stimulated emission by using detailed balance arguments. Half a century later, Scovil and Schulz-DuBois applied detailed balance ideas to show that maser photons were produced with Carnot quantum efficiency (see Fig. 1A). Furthermore, Shockley and Quiesser invoked detailed balance to obtain the efficiency of a photocell illuminated by “hot” thermal light (see Fig. 2A). To understand this detailed balance limit, we note that in the QHE, the incident light excites electrons, which can then deliver useful work to a load. However, the efficiency is limited by radiative recombination in which the excited electrons are returned to the ground state. But it has been proven that radiatively induced quantum coherence can break detailed balance and yield lasing without inversion. Here we show that noise-induced coherence enables us to break detailed balance and get more power out of a laser or photocell QHE. Surprisingly, this coherence can be induced by the same noisy (thermal) emission and absorption processes that drive the QHE (see Fig. 3A). Furthermore, this noise-induced coherence can be robust against environmental decoherence.Fig. 1. (A) Schematic of a laser pumped by hot photons at temperature Th (energy source, blue) and by cold photons at temperature Tc (entropy sink, red). The laser emits photons (green) such that at threshold the laser photon energy and pump photon energy is related by Carnot efficiency (4). (B) Schematic of atoms inside the cavity. Lower level b is coupled to the excited states a and β. The laser power is governed by the average number of hot and cold thermal photons, and . (C) Same as B but lower b level is replaced by two states b1 and b2, which can double the power when there is coherence between the levels.Fig. 2. (A) Schematic of a photocell consisting of quantum dots sandwiched between p and n doped semiconductors. Open circuit voltage and solar photon energy ℏνh are related by the Carnot efficiency factor where Tc is the ambient and Th is the solar temperature. (B) Schematic of a quantum dot solar cell in which state b is coupled to a via, e.g., solar radiation and coupled to the valence band reservoir state β via optical phonons. The electrons in conduction band reservoir state α pass to state β via an external circuit, which contains the load. (C) Same as B but lower level b is replaced by two states b1 and b2, and when coherently prepared can double the output power.Fig. 3. (A) Photocell current j = Γραα (laser photon flux Pl/ℏνl) (in arbitrary units) generated by the photovoltaic cell QHE (laser QHE) of Fig. 1C (Fig. 2C) as a function of maximum work (in electron volts) done by electron (laser photon) Eα - Eβ + kTc log(ραα/ρββ) with full (red line), partial (brown line), and no quantum interference (blue line). (B) Power of a photocell of Fig. 2C as a function of voltage for different decoherence rates , 100γ1c. Upper curve indicates power acquired from the sun.
[1]
Marlan O Scully,et al.
Quantum photocell: using quantum coherence to reduce radiative recombination and increase efficiency.
,
2010,
Physical review letters.
[2]
A. Einstein.
Über einen die Erzeugung und Verwandlung des Lichtes betreffenden heuristischen Gesichtspunkt [AdP 17, 132 (1905)]
,
2005,
Annalen der Physik.
[3]
E. O. Schulz-DuBois,et al.
Three-Level Masers as Heat Engines
,
1959
.
[4]
M. Lee.
Carnot cycle for photon gas
,
2001
.
[5]
D. Herschbach,et al.
Statistical mechanics of pendular molecules
,
1996
.
[6]
G. Agarwal.
Quantum statistical theories of spontaneous emission and their relation to other approaches
,
1974
.
[7]
Carlo Sirtori,et al.
Controlling the sign of quantum interference by tunnelling from quantum wells
,
1997,
Nature.
[8]
Victor V. Kozlov,et al.
Inducing quantum coherence via decays and incoherent pumping with application to population trapping, lasing without inversion, and quenching of spontaneous emission
,
2006
.
[9]
Marlan O. Scully,et al.
Fano interference of collective excitations in semiconductor quantum wells and lasing without inversion
,
1999
.
[10]
S. Harris,et al.
Electromagnetically Induced Transparency
,
1991,
QELS '97., Summaries of Papers Presented at the Quantum Electronics and Laser Science Conference.
[11]
D. Tannor,et al.
Three-level systems as amplifiers and attenuators: a thermodynamic analysis.
,
2007,
Physical review letters.
[12]
Wolfgang P. Schleich,et al.
Quantum optics in phase space
,
2001
.
[13]
E. Pringsheim,et al.
On the Law of Distribution of Energy in the Normal Spectrum
,
2003
.
[14]
M. Scully,et al.
Lasing without inversion and enhancement of the index of refraction via interference of incoherent pump processes
,
1992
.
[15]
A. Barut.
Quantization of collective regular structures of particles
,
1995
.
[16]
A. Kirk.
Analysis of quantum coherent semiconductor quantum dot p-i-n junction photovoltaic cells.
,
2011,
Physical review letters.
[17]
H. Queisser,et al.
Detailed Balance Limit of Efficiency of p‐n Junction Solar Cells
,
1961
.
[18]
M. Planck.
Ueber das Gesetz der Energieverteilung im Normalspectrum
,
1901
.
[19]
Olga Kocharovskaya,et al.
Amplification and lasing without inversion
,
1992
.
[20]
Einstein ( 1905 ) : " On a Heuristic Point of View Concerning the Production and Transformation of Light "
,
2007
.