Deformation theory of deformed Donaldson-Thomas connections for Spin(7)-manifolds

Abstract

A deformed Donaldson-Thomas connection for a manifold with a Spin(7)-structure, which we call a Spin(7)-dDT connection, is a Hermitian connection on a Hermitian line bundle L over a manifold with a Spin(7)-structure defined by fully nonlinear PDEs. It was first introduced by Lee and Leung as a mirror object of a Cayley cycle obtained by the real Fourier-Mukai transform and its alternative definition was suggested in our other paper. As the name indicates, a Spin(7)-dDT connection can also be considered as an analogue of a Donaldson-Thomas connection ( Spin(7)-instanton). In this paper, using our definition, we show that the moduli space M Spin(7) of Spin(7)-dDT connections has similar properties to these objects. That is, we show the following for an open subset M' Spin(7) ⊂ M Spin(7). (1) Deformations of elements of M' Spin(7) are controlled by a subcomplex of the canonical complex introduced by Reyes Carri\'on by introducing a new Spin(7)-structure from the initial Spin(7)-structure and a Spin(7)-dDT connection. (2) The expected dimension of M' Spin(7) is finite. It is b1, the first Betti number of the base manifold, if the initial Spin(7)-structure is torsion-free. (3) Under some mild assumptions, M' Spin(7) is smooth if we perturb the initial Spin(7)-structure generically. (4) The space M' Spin(7) admits a canonical orientation if all deformations are unobstructed.

0

Turn this paper into a full lesson

ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.

Discussion (0)

Sign in to join the discussion.

Loading comments…