Heat conduction induced by non-Gaussian athermal fluctuations

2013/07/03 Physics of Granular Flows @YITP
Heat conduction induced by non-Gaussian athermal fluctuations
Difference between thermal & athermal fluctuation Kiyoshi Kanazawa (YITP) Takahiro Sagawa (Tokyo Univ.) Hisao Hayakawa (YITP)

Introduction:Thermodynamics for small systems

To understand small systems Thermal noise small systems (μm～nm)(Ex. Colloidal particles)→manipulation of small systems (Ex. Optical tweezers) Role of fluctuations→Feynman Ratchet (heat engine/ heat conduction) Framework for small system(Theoretical limit of manipulation) laser

Analogy between Macro & Micro Macroscopic thermodynamics Microscopic thermodynamics macro bath & macro system Work& Heat (The 1st law) Irreversibility(The 2nd law) Efficiency(Carnotefficiency) macro bath& micro system(Ex) water& colloidal particle Manipulation (Optical tweezers) The 1st & 2nd laws? Efficiency of small systems Heat Bath (Macroscopic) Heat Bath (Macroscopic) Microscopic Macroscopic System cmorder order

Brownian particle trapped by optical tweezers(“Single particle gas”) Langevin Eq. with a potential( width of the potential) white Gaussian noise Can we define thermodynamic quantities (work) & (heat)? (for this manipulation process) laser Colloidal particle water small⇔ compression big ⇔ expansion

The 1st law for small systems(Stochastic energetics) (work) = macro degrees of freedom (heat) = micro degrees of freedom Environmental effect (micro degrees of freedom) K. Sekimoto, Prog. Theor. Phys. Supp. 130, 17 (1998).K. Sekimoto, Stochastic Energetics (Springer). K. Kanazawa et. al., Phys. Rev. Lett.108, 210601 (2012).

The 2nd law for small systems Average of workobeys the 2nd law! Maximum efficiency is achievedfor quasi-staticprocesses! laser Equality holds for quasi-static processes Colloidal particle water

Heat conduction for small systems Small systems ()Ex.) Biological motors Nanotubes Characterized byNon-equilibrium equalities Non-equilibrium equalities Fourier law Average Heat Fluctuation relation Fluctuation

Electrical circuits (LRC) Experimental realization (S. Cilibertoet al. (2013)) Thermal Thermal Brownian motor (spring) Vanes (Angles ) driven by noises () & viscosity Spring synchronizes the angles Heat Gaussian noise Detail

Summary of introduction The 1st law→ The 2nd law→ Thermodynamics for small systems Fourier law Fluctuation relation Non-equilibrium equalities

Main: Heat conduction induced by non-Gaussian fluctuations

Thermal & athermal fluctuations Thermal noise (Gauss noise) Fluctuation Thermal fluctuation→from eq. environmentEx.)Nyquistnoise Brownian noise Athermal noise (Non-Gaussian) Athermal fluctuation→from noneq. environmentEx.)Electrical shotnoiseBiological fluctuation Granular noise

Poisson noise(shot noise) Weak electrical current→particle property→”come” or “do not come”(spike noise） A typical of non-Gaussian noise Noises happen times per unit time.Intensity (fight distanse) = E

Athermal env. & non-Gaussian noise Fluctuations in athermal env. ⇒ non-Gaussian noise (i) Shot & burst noise in electrical circuits Ex. (ii) Membrane of Red Blood Cell with ATP receptions Apply shot noise (zero-mean) Non-Gaussian Gaussian Thermal Env. Athermal Env. Abstraction water ATP

What corrections appear in the Fourier law? Between thermal systems Between athermal systems Fourier law (FL) Fluctuation theorem (FT) Extension of FL & FT? Correction terms? + Correction? Correction? Thermal() Thermal() Athermal Athermal conductingwire conductingwire

Non-equilibrium Brownian motor conducting wire Non-Gaussian noise（） Non-Gaussiannoise（） Non-Gaussian athermal fluctuations A conducting wire synchronizing the angles Heat() Athermal Athermal Langevin Eq. Non-Gaussian K. Kanazawa et. al., PRL, 108, 210601 (2012) Heat Characterization of non-Gaussianity

(i) Generalized Fourier Law Perturbation in terms of Not only but also contribute to . coupling

Harmonic potential Quartic potential Corresponding correction The ordinary Fourier law Correspondence coupling

Numerical check of GFL(Setup) Gaussian vs. Two-sided Poisson Gaussian noise (thermal) Two-sided Poisson noise (athermal) Variance = 2T High order cumulants = 0 Flight distance = Transition rate =

Numerical check of GFL(Results) Quartic potential Changing the parameter The direction of heat current depends on We can change the direction of heat current by choosing an appropriate conducting wire

(ii)Absence of the 0th law B Does the 0th law exists? （Equilibrium between A and B, B and C → A and C） The direction of heat depends on the device.←Violation of the 0th law But, the 0th law recovers if we fix the device.(+we can define effective temperature.) eq. eq. ＡＣ eq. Absent for athermal systems

(iii) Generalized Fluctuation theorem Perturbation in terms of Harmonic Potential → Ordinary Fourier law But, the fluctuation theorem is modified.

In a case of the Gaussian & two-sided Poisson noise We can further sum up the expansion! A special case of the Gaussian and two-sided Poisson noise

Numerical check of the linear part ofthe generalized fluctuation relation The Gaussian vs. two-sided Poisson case Consistent with our generalized FTnot with the conventional FT Conventional Modified

Conclusion Generalized Fourier law Generalized fluctuation theorem Violation of the 0st lawThe direction of heat depends on the contact device(If we fix the contact device, the 0th law recovers) Non-Gaussian Brownian motor K. Kanazawa, T. Sagawa, and H. Hayakawa, Phys. Rev. E 87, 052124 (2013)

Heat conduction induced by non-Gaussian athermal fluctuations