Motivic degree zero Donaldson–Thomas invariants

Abstract: Given a smooth complex threefold X, we define the virtual motive [Hilb n (X)] vir of the Hilbert scheme of n points on X. In the case when X is Calabi-Yau, [Hilb n (X)] vir gives a motivic refinement of the n-point degree zero Donaldson-Thomas invariant of X. The key example is X = C 3 , where the Hilbert scheme can be expressed as the critical locus of a regular function on a smooth variety, and its virtual motive is defined in terms of the Denef-Loeser motivic nearby fiber. A crucial technical result asserts… Show more

“…-Instead of classifying objects up to isomorphism, we could allow weaker equivalences. For example, we could identify to families V (1) and V (2) (over S) of vector spaces or representations of an algebra A if there is a line bundle L on S such that…”

“…Every vector bundle V of rank r provides such a bundle by taking P := P(V ), the bundle of lines or hyperplanes in V . Two vector bundles V (1) , V (2) define isomorphic bundles P(V (1) ) ∼ = P(V (2) ) if and only if…”

“…Hint: Relate the slope of V / ker(f ) = im(f ) to µ(V (1) ) and to µ(V (2) ) by drawing the central charges of all objects involved. (2) Using the notation of the first part, let us assume µ(V (1) ) = µ(V (2) ) for the semistable representations V (1) , V (2) . Show that ker(f ) and coker(f ) are also semistable of the same slope µ(V (1) ).…”

“…(2) Use Exercise 3.12(1) to construct a Harder-Narasimhan filtration. Hint: Let V (1) be the subrepresentation constructed in the first step, and let V (2) be the preimage of a maximal subrepresentation in V /V (1) of maximal slope. Proceed in this way, and use the previous exercise to estimate the slopes.…”

“…The case of zero potential has been intensively studied by M. Reineke in a series of papers [30,31,32]. Despite some computations of motivic or even numerical Donaldson-Thomas invariants for quivers with potential (see [2,6,4,27]), the true nature of Donaldson-Thomas invariants for quiver with potential remained mysterious for quite some time. A full understanding has been obtained recently and is the content of a series of papers [7,5,26,24].…”

An Introduction to (Motivic) Donaldson-Thomas Theory

“…-Instead of classifying objects up to isomorphism, we could allow weaker equivalences. For example, we could identify to families V (1) and V (2) (over S) of vector spaces or representations of an algebra A if there is a line bundle L on S such that…”

“…Every vector bundle V of rank r provides such a bundle by taking P := P(V ), the bundle of lines or hyperplanes in V . Two vector bundles V (1) , V (2) define isomorphic bundles P(V (1) ) ∼ = P(V (2) ) if and only if…”

“…Hint: Relate the slope of V / ker(f ) = im(f ) to µ(V (1) ) and to µ(V (2) ) by drawing the central charges of all objects involved. (2) Using the notation of the first part, let us assume µ(V (1) ) = µ(V (2) ) for the semistable representations V (1) , V (2) . Show that ker(f ) and coker(f ) are also semistable of the same slope µ(V (1) ).…”

“…(2) Use Exercise 3.12(1) to construct a Harder-Narasimhan filtration. Hint: Let V (1) be the subrepresentation constructed in the first step, and let V (2) be the preimage of a maximal subrepresentation in V /V (1) of maximal slope. Proceed in this way, and use the previous exercise to estimate the slopes.…”

“…The case of zero potential has been intensively studied by M. Reineke in a series of papers [30,31,32]. Despite some computations of motivic or even numerical Donaldson-Thomas invariants for quivers with potential (see [2,6,4,27]), the true nature of Donaldson-Thomas invariants for quiver with potential remained mysterious for quite some time. A full understanding has been obtained recently and is the content of a series of papers [7,5,26,24].…”

An Introduction to (Motivic) Donaldson-Thomas Theory

Framed motivic Donaldson–Thomas invariants of small crepant resolutions

Degree 0 DT Invariants of a Local Calabi–Yau 3-Fold