Morse theory for the Yang-Mills energy function near flat connections

Abstract

A result (Corollary 4.3) in an article by Uhlenbeck (1985) asserts that the W1,p-distance between the gauge-equivalence class of a connection A and the moduli subspace of flat connections M(P) on a principal G-bundle P over a closed Riemannian manifold X of dimension d≥ 2 is bounded by a constant times the Lp norm of the curvature, \|FA\|Lp(X), when G is a compact Lie group, FA is Lp-small, and p>d/2. While we prove that this estimate holds when the Yang-Mills energy function on the space of Sobolev connections is Morse-Bott along the moduli subspace M(P) of flat connections, it does not hold when the Yang-Mills energy function fails to be Morse-Bott, such as at the product connection in the moduli space of flat SU(2) connections over a real two-dimensional torus. However, we prove that a useful modification of Uhlenbeck's estimate always holds provided one replaces \|FA\|Lp(X) by a suitable power \|FA\|Lp(X)λ, where the positive exponent λ reflects the structure of non-regular points in M(P). The proof of our refinement involves gradient flow and Morse theory for the Yang-Mills energy function on the quotient space of Sobolev connections and a Lojasiewicz distance inequality for the Yang-Mills energy function. A special case of our estimate, when X has dimension four and the connection A is anti-self-dual, was proved by Fukaya (1998) by entirely different methods. Lastly, we prove that if A is a smooth Yang-Mills connection with small enough energy, then A is necessarily flat.