6533b7dcfe1ef96bd127338b
RESEARCH PRODUCT
Nanoscale Heat Engine Beyond the Carnot Limit
Eric LutzJ. RoßnagelObinna AbahFerdinand Schmidt-kalerKilian Singersubject
Condensed Matter::Quantum GasesPhysicsThermal reservoirMaximum power principleMonte Carlo methodGeneral Physics and AstronomyMechanicssymbols.namesakeQuantum mechanicssymbolsOtto cycleCarnot cycleQuantum thermodynamicsHarmonic oscillatorHeat enginedescription
We consider a quantum Otto cycle for a time-dependent harmonic oscillator coupled to a squeezed thermal reservoir. We show that the efficiency at maximum power increases with the degree of squeezing, surpassing the standard Carnot limit and approaching unity exponentially for large squeezing parameters. We further propose an experimental scheme to implement such a model system by using a single trapped ion in a linear Paul trap with special geometry. Our analytical investigations are supported by Monte Carlo simulations that demonstrate the feasibility of our proposal. For realistic trap parameters, an increase of the efficiency at maximum power of up to a factor of 4 is reached, largely exceeding the Carnot bound.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2013-09-12 | Physical Review Letters |