Let K ⊂ C be compact. Then its analytic capacity is defined to be Here, denotes the set of bounded analytic functions U → C, whenever U is an open subset of the complex plane. Further, Note that, where. However, usually. If A ⊂ C is an arbitrary set, then we define
Removable sets and Painlevé's problem
The compact setK is called removable if, whenever Ω is an open set containing K, every function which is bounded and holomorphic on the set Ω \ K has an analytic extension to all of Ω. By Riemann's theorem for removable singularities, every singleton is removable. This motivated Painlevé to pose a more general question in 1880: "Which subsets of C are removable?" It is easy to see that K is removable if and only ifγ = 0. However, analytic capacity is a purely complex-analytic concept, and much more work needs to be done in order to obtain a more geometric characterization.
Ahlfors function
For each compact K ⊂ C, there exists a unique extremal function, i.e. such that, f = 0 and f′ = γ. This function is called the Ahlfors function of K. Its existence can be proved by using a normal family argument involving Montel's theorem.
Let dimH denote Hausdorff dimension and H1 denote 1-dimensional Hausdorff measure. Then H1 = 0 implies γ = 0 while dimH > 1 guarantees γ > 0. However, the case when dimH = 1 and H1 ∈ (0, ∞] is more difficult.
Positive length but zero analytic capacity
Given the partial correspondence between the 1-dimensional Hausdorff measure of a compact subset of C and its analytic capacity, it might be conjectured that γ = 0 implies H1 = 0. However, this conjecture is false. A counterexample was first given by A. G. Vitushkin, and a much simpler one by J. Garnett in his 1970 paper. This latter example is the linear four cornersCantor set, constructed as follows: Let K0 := × be the unit square. Then, K1 is the union of 4 squares of side length 1/4 and these squares are located in the corners of K0. In general, Kn is the union of 4n squares of side length 4−n, each being in the corner of some. Take K to be the intersection of all Kn then but γ = 0.
Vitushkin's conjecture
Let K ⊂ C be a compact set. Vitushkin's conjecture states that where denotes the orthogonal projection in direction θ. By the results described above, Vitushkin's conjecture is true when dimHK ≠ 1. Guy David published a proof in 1998 of Vitushkin's conjecture for the case dimHK = 1 and H1 < ∞. In 2002, Xavier Tolsa proved that analytic capacity is countably semiadditive. That is, there exists an absolute constant C > 0 such that if K ⊂ C is a compact set and, where each Ki is a Borel set, then. David's and Tolsa's theorems together imply that Vitushkin's conjecture is true when K is H1-sigma-finite. However, the conjecture is still open for K which are 1-dimensional and not H1-sigma-finite.
