quantum feynman ratchet ryoichi kawaistochastic thermodynamics langevin approach stochastic...
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Quantum Feynman Ratchet
Ryoichi KawaiDepartment of Physics
University of Alabama at Birmingham
Nanyang Technological University, Singapore (May 3, 2015)
Ketan Goyal
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1.Introduction/Motivation2.Review of Classical Feynman Ratchet3.A Model of Quantum Feynman Ratchet4.Open Quantum Mechanics Approach5.Heat, Work, and Efficiency6.Entanglement Measure7.Effect of Projective Measurement8.Conclusions
Contents
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Motivation
MacroscopicNo Fluctuation
Thermodynamics
MesoscopicC-Fluctuation
StochasticThermodynamics
Langevin ApproachStochastic EnergeticsFluctuation TheoremJarzynski EqualityKPB Equality
QuantumThermodynamics
MicroscopicQ-Fluctuation
Heat Bath?Equation of Motion?Thermodynamic Quantities?Quantum Correlation? (Entanglement, Discord)Quantum Measurement?
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T 1T 2
Q1 Q2
W
System is simultaneously in contact with
multiple heat baths.
ST 1 T 2Q1 Q2
W
S
W
S
System is alternativelyin contact withone heat bath
at a time
Cyclic Heat Engine (time-dependent)
λ (t )
λ (t )
Driven Heat Engine(time-dependent)
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T 1T 2
Q1 Q2
W
System is simultaneously in contact with
multiple heat baths.
S
Autonomous Heat Engine
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What is Heat and Work?Stochastic Thermodynamics
Langevin Equation:
1st Law is satisfied.
(Mechanical definitions agree with the thermodynamics law.)
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What is Heat and Work in Quantum Thermodynamics Processes?
(Time-Dependent Case)
Define the internal energy and then identify heat and worksuch that the 1st law is satisfied.
The expectation value --> non-selective measurement.
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if the previous definition is used.
Steady State
What is Heat and Work in Quantum Thermodynamics Processes?
(Steady State Case)
Heat and work are defined to satisfy 1st law without mechanical consideration.
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Criticism
Heat and work are change in certain types of energy and must be measured at two different times .
without measurement
with measurement
the order of measurements affects the outcome. If
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Should we use POVM instead of PVM?
Roncaglia, Cerisola, Paz: PRL (2014)
Campisi, Talkner, Hanggi: PRE(2011), Yi and Kim: PRE(2013)
What is the time derivative of expectation value?
(Quantum Zeno effect?)
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Measurement injects energy into the system.
Is the energy cost of measurement a part of thermodynamic energy transaction?
How to extract work from the system?
Th work media can be even entangled to the system.
[Non-demolition measurement? Gelbwaser-Klimovsky et al., PRA (2013)]
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Feynman Ratchet
The Feynman Lectureon Physics, Vol. I
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L
q
Feynman's Analysis
Forward Backward
Carnot efficiency is attainable at the vanishing power
Efficiency
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Van den Broeck, Kawai, and Meurs, PRL (2004)Van den Broeck and Kawai, PRL (2006)Fruleux, Kawai, and Sekimoto, PRL (2012)
Failure of Feynman's Analysis
Parrondo and Espanol (1996), Sekimoto (1997)
Feynman overlooked fluctuations. Fluctuations transportheat even when work vanishes.At the stalled state, power vanishes but heat does not.Hence, the efficiency is zero.
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T 1 T 2
A B
C
Youssef, Mahler, and Obada (2009), Linden, Popescu, and Skrzypczyk (2010)
A Model of Quantum Feynman Ratchet
EBE A
ℏω
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T
A
Quantum Open System Approach
● Born-approximation● Markovian approximation● Rotating-wave approximation● Neglecting Lamb-shift
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Youssef, Mahler, and Obada (2009)Linden, Popescu, and Skrzypczyk (2010)
A Tripartite Modelwith Weak Coupling Approximation
T 1 T 2
A B
C
EBE A
ℏω
They claimed that this heat engine can attain the Carnot efficiency.
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T
A B
Composite System
● Rigorously speaking, this approach is wrong.● Detailed balance is not satisfied.● Incorrect thermal equilibrium state.
● It may be valid under the weak coupling limit.
Correct dissipation function
Carmichael(1973)Nakatani (2010)
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A Tripartite Modelwithout Weak Coupling Approximation
T 1 T 2
A B
C
EBE A
ℏω
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T 1 T2
A B
C
EBE A
ℏω
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Heat and Work
Heat Current
Heat Current Operator
Power
Power Operator
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resonanttransitionE
Bħω
EB
ħω
Weak Coupling Limit
Exact
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T 1 T2
A B
C
EBE A
ℏω
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“Thermodynamics”without measurement
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Entanglement Measure
There is no perfect measure of entanglement for mixed states,particularly tripartite or higher order composite systems.
block diagonal
Concurrence: Entanglement Measure for
If it is positive, there is entanglement between two q-bits.
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Positive Partial Transpose (PPT)
C
A B
Entanglement between B and composite system AC
Partial Transpose
If at least one of eigenvalues is negative, there is entanglement.
(Converse is not true.)
Negativity
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Entanglement
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Effect of Measurements
Projective measurement of photon number
without measurement
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Measurement destroys the entanglement
But it recovers rather quickly.
without measurement
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Conclusions
● A Model of Quantum Feynman ratchet is investigated using a standard open quantum mechanics approach and popular definition of thermodynamic quantities.
● It is shown that heat flows even at the stalled condition through quantum fluctuation (entanglement). Thus, the Carnot efficiency is not attainable.
● The effect of measurement is found to be minimal. Both thermodynamic quantities and entanglement recovers quickly.
There is a hope!We may be able to construct quantum thermodynamics without worrying about measurement issues using proper time coarse-graining.