Cyclic source pairings for Penrose--Sparling non-Hausdorff twistor spaces

Abstract

We introduce noncommutative geometry techniques in order to reinterpret the Penrose--Sparling non-Hausdorff twistor space of the anti-self-dual Coulomb field by means of an explicit etale gluing groupoid and its convolution algebra. This algebraic model keeps track of both the identified open part and the two non-separated copies of the source quadric. We compute two kinds of Chern--Connes pairings. The strict tangent-module analogue, obtained from \([T R3]\), vanishes because \[ ch3(T1,03)+ ch3(T0,13)=0. \] By contrast, the Penrose--Sparling Coulomb line bundle \(n\) defines a \(K0(AQ)\)-class, and the relative cyclic cocycle supported on the two non-separated copies of a ruling line \(L⊂ Q\) gives \[ Q(n)= 12 φL+-φL-,[n]=n. \] Thus the source-adapted cyclic pairing recovers the Coulomb charge. We also formulate the non-abelian version in principal-bundle language. For a connected complex reductive group \(G\), a maximal torus \(T⊂ G\), and a cocharacter \(λ:* T\), the source is a principal \(G\)-bundle modification of type \(λ\) along \(Q\).