AbstractUnderstanding processes associated with eddy‐mean flow interactions helps our interpretation of ocean energetics, and guides the development of parameterizations. Here, we focus on the non‐local nature of Kinetic Energy (KE) transfers between mean and turbulent reservoirs. Transfers are interpreted as non‐local when the energy extracted from the mean flow does not locally sustain an growth of energy in the turbulent flow, or vice versa. The novelty of our approach is to use ensemble statistics to define the mean and the turbulent flow. Based on KE budget considerations, we first rationalize the eddy‐mean separation in the ensemble framework, and discuss the interpretation of a mean flow driven by the prescribed (surface and boundary) forcing and a turbulent flow u′ driven by non‐linear dynamics sensitive to initial conditions. We then analyze 120‐day long, 20‐member ensemble simulations of the Western Mediterranean basin run at resolution. Our main contribution is to recognize the prominent contribution of the cross energy term to explain non‐local energy transfers, which provides a strong constraint on the horizontal organization of eddy‐mean flow KE transfers since the cross energy term vanishes identically for perturbations orthogonal to the mean flow . We also highlight the prominent contribution of vertical turbulent fluxes for energy transfers within the surface mixed layer. Analyzing the scale dependence of non‐local energy transfers supports the local approximation usually made in the development of meso‐scale, energy‐aware parameterizations for non‐eddying models, but points out to the necessity of accounting for non‐local dynamics in the meso‐to‐submeso scale range.