SU(2) representations and a large surgery formula

Abstract

A knot K⊂ S3 is called SU(2)-abundant if it satisfies two conditions: first, for all but finitely many r∈Q\0\, there exists an irreducible representation π1(S3r(K)) SU(2); second, any slope r=u/v≠ 0 for which S3r(K) admits no irreducible SU(2) representation must satisfy K(ζ2)= 0 for some u-th root of unity ζ. We show that if a nontrivial knot K⊂ S3 is not SU(2)-abundant then it is a prime knot whose Alexander polynomial K(t) has coefficients restricted to \-1,0,1\. This implies, in particular, that all hyperbolic alternating knots are SU(2)-abundant. Our proof hinges on a large surgery formula connecting instanton knot homology KHI(S3,K) and framed instanton homology I(S3n(K)) for integers n satisfying |n| 2g(K)+1. Using this technique, we derive several interesting results in instanton Floer homology: for any Berge knot K, the spaces KHI(S3,K) and HFK(S3,K) have identical dimension; for any dual knot Kr⊂ S3r(K) of a Berge knot K with r> 2g(K)-1, we prove CKHI(S3r(K),Kr)=|H1(S3r(K);Z)|; and for any genus-one alternating knot K and any r∈Q\0\, the spaces I(S3r(K)) and HF(Sr3(K)) have equal dimension.