Transport and Interface: an Uncertainty Principle for the Wasserstein distance

Abstract

Let f: [0,1]d → R be a continuous function with zero mean and interpret f+ = (f, 0) and f- = -(f, 0) as the densities of two measures. We prove that if the cost of transport from f+ to f- is small (in terms of the Wasserstein distance W1), then the nodal set \x ∈ (0,1)d: f(x) = 0 \ has to be large (`if it is always easy to buy milk, there must be many supermarkets'). More precisely, we show that W1(f+, f-) · Hd-1\x ∈ (0,1)d: f(x) = 0 \ d ( \|f\|L1\|f\|L∞ )4 - 1d \|f\|L1 \, . We apply this ``uncertainty principle" to the metric Sturm-Liouville theory in higher dimensions to show that a linear combination of eigenfunctions of an elliptic operator cannot have an arbitrarily small zero set.