In mathematics, and especially algebraic geometry, a Bridgeland stability condition, defined by Tom Bridgeland, is an algebro-geometric stability condition defined on elements of a triangulated category. The case of original interest and particular importance is when this triangulated category is the derived category of coherent sheaves on a Calabi–Yau manifold, and this situation has fundamental links to string theory and the study of D-branes.
Such stability conditions were introduced in a rudimentary form by Michael Douglas called -stability and used to study BPS B-branes in string theory. [1] This concept was made precise by Bridgeland, who phrased these stability conditions categorically, and initiated their study mathematically. [2]
The definitions in this section are presented as in the original paper of Bridgeland, for arbitrary triangulated categories. [2] Let be a triangulated category.
A slicing of is a collection of full additive subcategories for each such that
The last property should be viewed as axiomatically imposing the existence of Harder–Narasimhan filtrations on elements of the category .
A Bridgeland stability condition on a triangulated category is a pair consisting of a slicing and a group homomorphism , where is the Grothendieck group of , called a central charge, satisfying
It is convention to assume the category is essentially small, so that the collection of all stability conditions on forms a set . In good circumstances, for example when is the derived category of coherent sheaves on a complex manifold , this set actually has the structure of a complex manifold itself.
It is shown by Bridgeland that the data of a Bridgeland stability condition is equivalent to specifying a bounded t-structure on the category and a central charge on the heart of this t-structure which satisfies the Harder–Narasimhan property above. [2]
An element is semi-stable (resp. stable) with respect to the stability condition if for every surjection for , we have where and similarly for .
Recall the Harder–Narasimhan filtration for a smooth projective curve implies for any coherent sheaf there is a filtration
such that the factors have slope . We can extend this filtration to a bounded complex of sheaves by considering the filtration on the cohomology sheaves and defining the slope of , giving a function
for the central charge.
There is an analysis by Bridgeland for the case of Elliptic curves. He finds [2] [3] there is an equivalence
where is the set of stability conditions and is the set of autoequivalences of the derived category .
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