Phase transitions in the totally asymmetric exclusion process with long-range hopping
J. Nossan, and K. Uzelac. Abstract Book of the XXIII IUPAP International Conference on Statistical Physics, Genova, Italy, (9-13 July 2007)
Abstract
Importance of the effective long-range interactions 1 appearing in asymmetric exclusion
processes (ASEP) raises the questions of possible consequences that an explicit
introduction of long-range effects might have on the boundary-induced phase
transitions in such systems. We investigate the 1d model for TASEP generalized to allow the
long-range hopping with the probability decaying with distance $l$ as $1/l^\sigma+1$.
Monte Carlo studies show that, with properly chosen boundary conditions, the phase diagram for
$\sigma>1$ remains the same as in the short-range case, but the density profiles display
additional features when $1<\sigma<2$ 2. At the first-order transition line we observe
the phase separation, which can be derived analytically in terms of the domain-wall theory
and shares some common features with TASEP in the presence of Langmuir kinetics 3.
In the maximum-current phase the density profile has an algebraic decay with an exponent that
depends on $\sigma$ for $1<\sigma<2$ and attains the short-range value $1/2$ for $\sigma2$.
We show that the same scaling exponent and its short-range limit are already present in the
numerical solution of the stationary equations for the density profile in the mean-field approximation.
Dynamic scaling related to the evolution towards the stationary state was also investigated.
We show, in the context of the domain-wall theory, that the dynamical exponent $z$ on the
coexistence line is equal to $2$ in the infinite-length limit. We also recover the KPZ exponent
$z=3/2$ for the case of the half-filled periodic chain both by Monte Carlo simulations and by
showing that the macroscopic density profile in the infinite chain evolves according to the
inviscid Burgers equation as in the short-range case.\\
1) B. Derrida, J.L. Lebowitz, E.R. Speer, Phys. Rev. Lett. 87, 150601 (2001)\\
2) J. Szavits-Nossan and K. Uzelac, Phys. Rev. E 74, 051104 (2006)\\
3) R. Juhász and L. Santen, J. Phys. A: Math. Gen. 37, 3933 (2004)
%0 Book Section
%1 statphys23_0788
%A Nossan, J. Szavits
%A Uzelac, K.
%B Abstract Book of the XXIII IUPAP International Conference on Statistical Physics
%C Genova, Italy
%D 2007
%E Pietronero, Luciano
%E Loreto, Vittorio
%E Zapperi, Stefano
%K asymmetric equilibrium exclusion hopping long-range out phase process statphys23 topic-3 transitions
%T Phase transitions in the totally asymmetric exclusion process with long-range hopping
%U http://st23.statphys23.org/webservices/abstract/preview_pop.php?ID_PAPER=788
%X Importance of the effective long-range interactions 1 appearing in asymmetric exclusion
processes (ASEP) raises the questions of possible consequences that an explicit
introduction of long-range effects might have on the boundary-induced phase
transitions in such systems. We investigate the 1d model for TASEP generalized to allow the
long-range hopping with the probability decaying with distance $l$ as $1/l^\sigma+1$.
Monte Carlo studies show that, with properly chosen boundary conditions, the phase diagram for
$\sigma>1$ remains the same as in the short-range case, but the density profiles display
additional features when $1<\sigma<2$ 2. At the first-order transition line we observe
the phase separation, which can be derived analytically in terms of the domain-wall theory
and shares some common features with TASEP in the presence of Langmuir kinetics 3.
In the maximum-current phase the density profile has an algebraic decay with an exponent that
depends on $\sigma$ for $1<\sigma<2$ and attains the short-range value $1/2$ for $\sigma2$.
We show that the same scaling exponent and its short-range limit are already present in the
numerical solution of the stationary equations for the density profile in the mean-field approximation.
Dynamic scaling related to the evolution towards the stationary state was also investigated.
We show, in the context of the domain-wall theory, that the dynamical exponent $z$ on the
coexistence line is equal to $2$ in the infinite-length limit. We also recover the KPZ exponent
$z=3/2$ for the case of the half-filled periodic chain both by Monte Carlo simulations and by
showing that the macroscopic density profile in the infinite chain evolves according to the
inviscid Burgers equation as in the short-range case.\\
1) B. Derrida, J.L. Lebowitz, E.R. Speer, Phys. Rev. Lett. 87, 150601 (2001)\\
2) J. Szavits-Nossan and K. Uzelac, Phys. Rev. E 74, 051104 (2006)\\
3) R. Juhász and L. Santen, J. Phys. A: Math. Gen. 37, 3933 (2004)
@incollection{statphys23_0788,
abstract = {Importance of the effective long-range interactions [1] appearing in asymmetric exclusion
processes (ASEP) raises the questions of possible consequences that an explicit
introduction of long-range effects might have on the boundary-induced phase
transitions in such systems. We investigate the 1d model for TASEP generalized to allow the
long-range hopping with the probability decaying with distance $l$ as $1/l^{\sigma+1}$.
Monte Carlo studies show that, with properly chosen boundary conditions, the phase diagram for
$\sigma>1$ remains the same as in the short-range case, but the density profiles display
additional features when $1<\sigma<2$ [2]. At the first-order transition line we observe
the phase separation, which can be derived analytically in terms of the domain-wall theory
and shares some common features with TASEP in the presence of Langmuir kinetics [3].
In the maximum-current phase the density profile has an algebraic decay with an exponent that
depends on $\sigma$ for $1<\sigma<2$ and attains the short-range value $1/2$ for $\sigma\geq 2$.
We show that the same scaling exponent and its short-range limit are already present in the
numerical solution of the stationary equations for the density profile in the mean-field approximation.
Dynamic scaling related to the evolution towards the stationary state was also investigated.
We show, in the context of the domain-wall theory, that the dynamical exponent $z$ on the
coexistence line is equal to $2$ in the infinite-length limit. We also recover the KPZ exponent
$z=3/2$ for the case of the half-filled periodic chain both by Monte Carlo simulations and by
showing that the macroscopic density profile in the infinite chain evolves according to the
inviscid Burgers equation as in the short-range case.\\
1) B. Derrida, J.L. Lebowitz, E.R. Speer, Phys. Rev. Lett. 87, 150601 (2001)\\
2) J. Szavits-Nossan and K. Uzelac, Phys. Rev. E 74, 051104 (2006)\\
3) R. Juh\'asz and L. Santen, J. Phys. A: Math. Gen. 37, 3933 (2004)},
added-at = {2007-06-20T10:16:09.000+0200},
address = {Genova, Italy},
author = {Nossan, J. Szavits and Uzelac, K.},
biburl = {https://www.bibsonomy.org/bibtex/2f055ce996344f8653e855db40e6db0d2/statphys23},
booktitle = {Abstract Book of the XXIII IUPAP International Conference on Statistical Physics},
editor = {Pietronero, Luciano and Loreto, Vittorio and Zapperi, Stefano},
interhash = {2bf9f5fcb5ccff3b128f592f4e55ac1b},
intrahash = {f055ce996344f8653e855db40e6db0d2},
keywords = {asymmetric equilibrium exclusion hopping long-range out phase process statphys23 topic-3 transitions},
month = {9-13 July},
timestamp = {2007-06-20T10:16:29.000+0200},
title = {Phase transitions in the totally asymmetric exclusion process with long-range hopping},
url = {http://st23.statphys23.org/webservices/abstract/preview_pop.php?ID_PAPER=788},
year = 2007
}