1. Evidence and quantification of memory effects in competitive first passage events
- Author
-
Dolgushev, M., Mendes, T. V., Gorin, B., Xie, K., Levernier, N., Bénichou, O., Kellay, H., Voituriez, R., and Guérin, T.
- Subjects
Condensed Matter - Statistical Mechanics - Abstract
Splitting probabilities quantify the likelihood of a given outcome out of competitive events for general random processes. This key observable of random walk theory, historically introduced as the Gambler's ruin problem for a player in a casino, has a broad range of applications beyond mathematical finance in evolution genetics, physics and chemistry, such as allele fixation, polymer translocation, protein folding and more generally competitive reactions. The statistics of competitive events is well understood for memoryless (Markovian) processes. However, in complex systems such as polymer fluids, the motion of a particle should typically be described as a process with memory. Appart from scaling theories and perturbative approaches in one-dimension, the outcome of competitive events is much less characterized analytically for processes with memory. Here, we introduce an analytical approach that provides the splitting probabilities for general $d$-dimensional non-Markovian Gaussian processes. This analysis shows that splitting probabilities are critically controlled by the out of equilibrium statistics of reactive trajectories, observed after the first passage. This hallmark of non-Markovian dynamics and its quantitative impact on splitting probabilities are directly evidenced in a prototypical experimental reaction scheme in viscoelastic fluids. Altogether, these results reveal both experimentally and theoretically the importance of memory effects on competitive reactions.
- Published
- 2024