Algebra and Algebraic Geometry Seminar Fall 2023: Difference between revisions
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In order to answer basic questions in modular and geometric representation theory, Bezrukavnikov and Kaledin introduced quantizations of symplectic varieties in positive characteristic. These are certain noncommutative algebras over a field of positive characteristic which have a large center. I will discuss recent work describing how to construct an important class of modules over such algebras. | In order to answer basic questions in modular and geometric representation theory, Bezrukavnikov and Kaledin introduced quantizations of symplectic varieties in positive characteristic. These are certain noncommutative algebras over a field of positive characteristic which have a large center. I will discuss recent work describing how to construct an important class of modules over such algebras. | ||
=== Andrei Negut === | |||
==== Computing K-HA's of quivers ==== | |||
Many interesting moduli stacks M in geometric representation theory admit interesting K-theoretic Hall algebras (K-HAs), defined by endowing the algebraic K-theory of M with an appropriate convolution product. While these algebras are notoriously hard to compute, they have an interesting relative called the shuffle algebra S. When M is a moduli stack of quiver representations, S is given by a collection of ideals inside polynomial rings, and their study can be reduced to commutative algebra. Fortunately/unfortunately, the commutative algebra in question is challenging, and we do not yet know of a complete description for a general quiver. In this talk, I will explain the general framework behind this problem, and survey results for the following special cases of quivers: | |||
* double quivers arising in the theory of Nakajima quiver varieties | |||
* quivers corresponding to symmetric Cartan matrices, yielding simply laced quantum loop groups | |||
* quivers associated to toric Calabi-Yau threefolds in mathematical physics | |||
===Purnaprajna Bangere=== | ===Purnaprajna Bangere=== |
Revision as of 17:52, 7 September 2023
The seminar normally meets 2:30-3:30pm on Fridays, in the room VV B223.
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Fall 2023 Schedule
date | speaker | title | host/link to talk |
---|---|---|---|
September 15 | Joshua Mundinger | Quantization in positive characteristic | local |
September 22 | Andrei Negut | Computing K-HA's of quivers | local |
November 17 | Purnaprajna Bangere | Syzygies of adjoint linear series on projective varieties | Michael K |
Abstracts
Joshua Mundinger
Quantization in positive characteristic
In order to answer basic questions in modular and geometric representation theory, Bezrukavnikov and Kaledin introduced quantizations of symplectic varieties in positive characteristic. These are certain noncommutative algebras over a field of positive characteristic which have a large center. I will discuss recent work describing how to construct an important class of modules over such algebras.
Andrei Negut
Computing K-HA's of quivers
Many interesting moduli stacks M in geometric representation theory admit interesting K-theoretic Hall algebras (K-HAs), defined by endowing the algebraic K-theory of M with an appropriate convolution product. While these algebras are notoriously hard to compute, they have an interesting relative called the shuffle algebra S. When M is a moduli stack of quiver representations, S is given by a collection of ideals inside polynomial rings, and their study can be reduced to commutative algebra. Fortunately/unfortunately, the commutative algebra in question is challenging, and we do not yet know of a complete description for a general quiver. In this talk, I will explain the general framework behind this problem, and survey results for the following special cases of quivers:
- double quivers arising in the theory of Nakajima quiver varieties
- quivers corresponding to symmetric Cartan matrices, yielding simply laced quantum loop groups
- quivers associated to toric Calabi-Yau threefolds in mathematical physics
Purnaprajna Bangere
Syzygies of adjoint linear series on projective varietiess
Syzygies of algebraic varieties have long been a topic of intense interest among algebraists and geometers alike. After the pioneering work of Mark Green on curves, numerous attempts have been made to extend some of these results to higher dimensions. It has been proposed that the syzygies of adjoint linear series L=K+mA, with A ample is a natural analogue for higher dimensions to explore. The very ampleness of adjoint linear series is not known for even threefolds. So the question that has been open for many years is the following (Question): If A is base point free and ample, does L satisfy property N_p for m>=n+1+p? Ein and Lazarsfeld proved this when A is very ample in 1991. In a joint work with Justin Lacini, we give a positive answer to the original question above.