Information Flow in geophysical systems

TL;DR

This paper introduces a novel framework for analyzing how information propagates in geophysical systems, revealing insights into causality, variable-specific dynamics, and potential applications in predictability and risk management.

Contribution

The paper presents a new framework for studying information flow in geophysical models, applied to nonlinear and atmospheric systems, highlighting unique propagation patterns and variable influences.

Findings

Information can propagate against fluid flow.

Different variables show distinct information evolution patterns.

Pressure and vorticity propagate differently, reflecting physical processes.

Abstract

We present a new framework for analyzing the evolution of information in geophysical systems. Understanding how information, and its counterpart, uncertainty, propagates is central to predictability studies and has significant implications for applications such as forecast uncertainty quantification and risk management. It also offers valuable insight into the underlying physics of the system. Information propagation is closely linked to causality: how one part of a system influences another, and how some regions remain dynamically isolated. We apply this framework to the one-dimensional, highly nonlinear Kuramoto-Sivashinsky model and to the shallow-water equations, representing a mid-latitude atmospheric strip. Notably, we observe that information can propagate against the fluid flow, and that different model variables exhibit distinct patterns of information evolution. For example, pressure-related information propagates differently from relative vorticity, reflecting the influence of gravity waves versus balanced flow dynamics. This new framework offers a promising addition to the diagnostic tools available for studying complex dynamical systems.