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Density large-deviations of nonconserving driven models STATPHYS 25 Conference, SNU, Seoul, Korea, July 2013 Or Cohen and David Mukamel.

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Presentation on theme: "Density large-deviations of nonconserving driven models STATPHYS 25 Conference, SNU, Seoul, Korea, July 2013 Or Cohen and David Mukamel."— Presentation transcript:

1 Density large-deviations of nonconserving driven models STATPHYS 25 Conference, SNU, Seoul, Korea, July 2013 Or Cohen and David Mukamel

2 T, µ Equilibrium Grand canonical ensemble out of equilibrium ?

3 T, µ Equilibrium Grand canonical ensemble out of equilibrium ? conserving steady state Helmholtz free energy

4 T, µ Equilibrium Grand canonical ensemble out of equilibrium ? conserving steady state Helmholtz free energy Driven system pq conserving steady state

5 T, µ Equilibrium Grand canonical ensemble out of equilibrium ? conserving steady state Helmholtz free energy Driven system pq e -βμ 1 conserving steady state

6 T, µ Equilibrium Grand canonical ensemble out of equilibrium ? conserving steady state Helmholtz free energy Driven system pq e -βμ 1 conserving steady state Dynamics-dependent chemical potential of conserving system

7 General particle-nonconserving driven model wRCwRC wLCwLC w - NC w + NC L sites

8 conserving (sum over η’ with same N) nonconserving (sum over η’ with N’≠N) wRCwRC wLCwLC w - NC w + NC L sites General particle-nonconserving driven model

9 wRCwRC wLCwLC w - NC w + NC Guess a steady state of the form : L sites conserving (sum over η’ with same N) nonconserving (sum over η’ with N’≠N) General particle-nonconserving driven model

10 It is consistent if : wRCwRC wLCwLC w - NC w + NC For diffusive systems L sites Guess a steady state of the form : conserving (sum over η’ with same N) nonconserving (sum over η’ with N’≠N) General particle-nonconserving driven model

11 Slow nonconserving dynamics To leading order in L we obtain

12 Slow nonconserving dynamics = 1D - Random walk in a potential

13 Slow nonconserving dynamics = 1D - Random walk in a potential

14 Slow nonconserving dynamics w - NC w + NC

15 Outline 1.Limit of slow nonconserving 2.Example of the ABC model 3.Corrections to the rate function using MFT 4.Conclusions

16 ABC model A BC AB BA BC CB CA AC Dynamics : q 1 q 1 q 1 Ring of size L M R Evans, Y Kafri, H M Koduvely, D Mukamel - Phys. Rev. Lett. 80 425 (1998 )

17 ABC model A BC AB BA BC CB CA AC Dynamics : q 1 q 1 q 1 Ring of size L q=1 q<1 M R Evans, Y Kafri, H M Koduvely, D Mukamel - Phys. Rev. Lett. 80 425 (1998 ) ABBCACCBACABACB AAAAABBBBBCCCCC

18 ABC model time site index A BC

19 Conserving ABC model 0X X0 X=A,B,C 1 1 AB C0 A Lederhendler, D Mukamel - Phys. Rev. Lett. 105 105602 (2010) A Lederhendler, OC, D Mukamel - J. Stat. Mech. 11 11016 (2010) A Lederhendler, D Mukamel - Phys. Rev. Lett. 105 105602 (2010) A Lederhendler, OC, D Mukamel - J. Stat. Mech. 11 11016 (2010) AB BA BC CB CA AC q 1 q 1 q 1 1 2 12 Conserving model (canonical ensemble) + fixed

20 Conserving ABC model 1.M Clincy, B Derrida, M R Evans - Phys. Rev. E 58 2764 (2003) Weakly asymmetric thermodynamic limit 1 Density profile

21 Conserving ABC model 1.M Clincy, B Derrida, M R Evans - Phys. Rev. E 58 2764 (2003) 2.OC, D Mukamel - J. Phys. A 44 415004 (2011) 1.M Clincy, B Derrida, M R Evans - Phys. Rev. E 58 2764 (2003) 2.OC, D Mukamel - J. Phys. A 44 415004 (2011) Weakly asymmetric thermodynamic limit 1 Density profile known 2 2 nd order For low β’s

22 Conserving ABC model 1.M Clincy, B Derrida, M R Evans - Phys. Rev. E 58 2764 (2003) 2.OC, D Mukamel - J. Phys. A 44 415004 (2011) 3.T Bodineau, B Derrida - Comptes Rendus Physique 8 540 (2007) 1.M Clincy, B Derrida, M R Evans - Phys. Rev. E 58 2764 (2003) 2.OC, D Mukamel - J. Phys. A 44 415004 (2011) 3.T Bodineau, B Derrida - Comptes Rendus Physique 8 540 (2007) Weakly asymmetric thermodynamic limit 1 Density profile known 2 2 nd order For low β’s Stationary measure 3 :

23 Nonconserving ABC model 0X X0 X=A,B,C 1 1 AB C0 AB BA BC CB CA AC q 1 q 1 q 1 ABC 000 pe -3βμ p 1 2 3 12 123 Conserving model (canonical ensemble) Nonconserving model (grand canonical ensemble) + ++ A Lederhendler, D Mukamel - Phys. Rev. Lett. 105 105602 (2010) A Lederhendler, OC, D Mukamel - J. Stat. Mech. 11 11016 (2010) A Lederhendler, D Mukamel - Phys. Rev. Lett. 105 105602 (2010) A Lederhendler, OC, D Mukamel - J. Stat. Mech. 11 11016 (2010)

24 Slow nonconserving ABC model Slow nonconserving limit ABC 000 pe -3βμ p

25 Slow nonconserving ABC model Slow nonconserving limit ABC 000 pe -3βμ p saddle point approx.

26 Slow nonconserving ABC model ABC 000 pe -3βμ p

27 Slow nonconserving ABC model ABC 000 pe -3βμ p This is similar to equilibrium : f = Helmholtz free energy density

28 Rate function of r, G(r) High µ Low µ First order phase transition (only in the nonconserving model) OC, D Mukamel - Phys. Rev. Let. 108, 060602 (2012)

29 Inequivalence of ensembles Conserving (Canonical) Nonconserving (Grand canonical) 2 nd order transition ordered 1 st order transitiontricritical point disordered ordered disordered For N A =N B ≠N C : OC, D Mukamel - Phys. Rev. Let. 108, 060602 (2012) Different nonconserving ABC model: J Barton, J L Lebowitz, E R Speer - J. Phys. A 44 065005 (2011) Discussion about ensemble inequivalence: OC, D Mukamel - J. Stat. Mech. 12 12017 (2012) OC, D Mukamel - Phys. Rev. Let. 108, 060602 (2012) Different nonconserving ABC model: J Barton, J L Lebowitz, E R Speer - J. Phys. A 44 065005 (2011) Discussion about ensemble inequivalence: OC, D Mukamel - J. Stat. Mech. 12 12017 (2012) Stability line

30 Corrections to G(r) using MFT ABC 000 pe -3βμ p - conserving action 1 - nonconserving action 2,3 - conserving current - nonconserving current 1.T Bodineau, B Derrida - Comptes Rendus Physique 8 540 (2007) 2.G Jona-Lasinio, C Landim and M E Vares - Probability theory and related fields 97 339 (1993) 3.T Bodineau, M Lagouge - J. Stat. Phys. 139 201 (2010) 1.T Bodineau, B Derrida - Comptes Rendus Physique 8 540 (2007) 2.G Jona-Lasinio, C Landim and M E Vares - Probability theory and related fields 97 339 (1993) 3.T Bodineau, M Lagouge - J. Stat. Phys. 139 201 (2010)

31 Corrections to G(r) using MFT ABC 000 pe -3βμ p τ r rμrμ 0 T Instanton path:

32 Conclusions 1.Nonequlibrium ‘grand canonical ensemble’ - Slow nonconserving dynamics 2.Example to ABC model 3.1 st order phase transition for nonmonotoneous µ s (r) and inequivalence of ensembles. ( µ s (r) is dynamics dependent ! ) 4.Corrections to rate function of r using MFT

33 Why is µ S (N) the chemical potential ? N1N1 N2N2 SLOW

34 Why is µ S (N) the chemical potential ? N1N1 N2N2 Gauge measures SLOW

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