Generic principles of active transport

Mauro Mobilia, et al. "Generic principles of active transport." Banach Center Publications 80.1 (2008): 101-120. <http://eudml.org/doc/282432>.

@article{MauroMobilia2008,
abstract = {Nonequilibrium collective motion is ubiquitous in nature and often results in a rich collection of intriguing phenomena, such as the formation of shocks or patterns, subdiffusive kinetics, traffic jams, and nonequilibrium phase transitions. These stochastic many-body features characterize transport processes in biology, soft condensed matter and, possibly, also in nanoscience. Inspired by these applications, a wide class of lattice-gas models has recently been considered. Building on the celebrated totally asymmetric simple exclusion process (TASEP) and a generalization accounting for the exchanges with a reservoir, we discuss the qualitative and quantitative nonequilibrium properties of these model systems. We specifically analyze the case of a dimeric lattice gas, the transport in the presence of pointwise disorder and along coupled tracks.},
author = {Mauro Mobilia, Tobias Reichenbach, Hauke Hinsch, Thomas Franosch, Erwin Frey},
journal = {Banach Center Publications},
keywords = {lattice-gas model; totally asymmetric simple exclusion process},
language = {eng},
number = {1},
pages = {101-120},
title = {Generic principles of active transport},
url = {http://eudml.org/doc/282432},
volume = {80},
year = {2008},
}

TY - JOUR
AU - Mauro Mobilia
AU - Tobias Reichenbach
AU - Hauke Hinsch
AU - Thomas Franosch
AU - Erwin Frey
TI - Generic principles of active transport
JO - Banach Center Publications
PY - 2008
VL - 80
IS - 1
SP - 101
EP - 120
AB - Nonequilibrium collective motion is ubiquitous in nature and often results in a rich collection of intriguing phenomena, such as the formation of shocks or patterns, subdiffusive kinetics, traffic jams, and nonequilibrium phase transitions. These stochastic many-body features characterize transport processes in biology, soft condensed matter and, possibly, also in nanoscience. Inspired by these applications, a wide class of lattice-gas models has recently been considered. Building on the celebrated totally asymmetric simple exclusion process (TASEP) and a generalization accounting for the exchanges with a reservoir, we discuss the qualitative and quantitative nonequilibrium properties of these model systems. We specifically analyze the case of a dimeric lattice gas, the transport in the presence of pointwise disorder and along coupled tracks.
LA - eng
KW - lattice-gas model; totally asymmetric simple exclusion process
UR - http://eudml.org/doc/282432
ER -