Statistical Theory for the Stochastic Burgers Equation in the Inviscid Limit

@misc{citeulike:2967534, abstract = {A statistical theory is developed for the stochastic Burgers equation in the inviscid limit. Master equations for the probability density functions of velocity, velocity difference and velocity gradient are derived. No closure assumptions are made. Instead closure is achieved through a dimension reduction process, namely the unclosed terms are expressed in terms of statistical quantities for the singular structures of the velocity field, here the shocks. Master equations for the environment of the shocks are further expressed in terms of the statistics of singular structures on the shocks, namely the points of shock generation and collisions. The scaling laws of the structure functions are derived through the analysis of the master equations. Rigorous bounds on the decay of the tail probabilities for the velocity gradient are obtained using realizability constraints. We also establish that the probability density function of the velocity gradient has a left power tail with exponent -7/2.}, author = {Weinan, E. and Eijnden, Eric V. }, citeulike-article-id = {2967534}, eprint = {chao-dyn/9904028}, keywords = {1d, burgers, velocity-increment}, month = {Apr}, posted-at = {2008-07-06 17:48:52}, priority = {2}, title = {Statistical Theory for the Stochastic Burgers Equation in the Inviscid Limit}, url = {http://arxiv.org/abs/chao-dyn/9904028}, year = {1999} }

TY - ELEC ID - citeulike:2967534 L3 - citeulike-article-id:2967534 TI - Statistical Theory for the Stochastic Burgers Equation in the Inviscid Limit N2 - A statistical theory is developed for the stochastic Burgers equation in the inviscid limit. Master equations for the probability density functions of velocity, velocity difference and velocity gradient are derived. No closure assumptions are made. Instead closure is achieved through a dimension reduction process, namely the unclosed terms are expressed in terms of statistical quantities for the singular structures of the velocity field, here the shocks. Master equations for the environment of the shocks are further expressed in terms of the statistics of singular structures on the shocks, namely the points of shock generation and collisions. The scaling laws of the structure functions are derived through the analysis of the master equations. Rigorous bounds on the decay of the tail probabilities for the velocity gradient are obtained using realizability constraints. We also establish that the probability density function of the velocity gradient has a left power tail with exponent -7/2. KW - 1d KW - burgers KW - velocity-increment AU - Weinan, E AU - Eijnden, Eric PY - 1999/Apr/15/ UR - http://arxiv.org/abs/chao-dyn/9904028 ER -