This work investigates how information influences the propagation of chaos in stochastic interacting particle systems under the mean-field limit. The problem centers on quantifying and analyzing chaos propagation in path space for systems governed by stochastic differential equations. We propose the first framework integrating information-theoretic principles into path-space chaos analysis: modeling chaos propagation as an information divergence problem over the space of sample paths, then leveraging the data processing inequality to reduce it to estimating drift-term discrepancies—thereby circumventing conventional techniques based on hypocoercivity or pseudo-inverses of diffusion matrices. Our approach unifies tools from stochastic analysis, McKean–Vlasov theory, and path-space probability measures. Validated on canonical second-order systems, the method substantially simplifies convergence proofs, enhances numerical stability, and improves generality across diverse mean-field models.

Propagation of chaos for interacting particle systems has been an active research topic over decades. We propose an alternative approach to study the mean-field limit of the stochastic interacting particle systems via tools from information theory. In our framework, the propagation of chaos is reduced to the space for driving processes with possible lower dimension. Indeed, after applying the data processing inequality, one only needs to estimate the difference between the drifts of the particle system and the mean-field Mckean stochastic differential equation. This point is particularly useful in situations where the discrepancy in the driving processes is more apparent than the investigated processes. We will take the second order system as well as other examples for the illustration of how our framework could be used. This approach allows us to focus on probability measures in path spaces for the driving processes, avoiding using the usual hypocoercivity technique or taking the pseudo-inverse of the diffusion matrix, which might be more stable for numerical computation. Our framework is different from current approaches in literature and could provide new insight into the study of interacting particle systems.