Algebraic Geometry Seminar Spring 2016: Difference between revisions
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The seminar meets on Fridays at 2:25 pm in Van Vleck B113. | The seminar meets on Fridays at 2:25 pm in Van Vleck B113. | ||
Here is the schedule for [[Algebraic Geometry Seminar Fall 2015 | the previous semester]] and for [[Algebraic Geometry Seminar | this semester]]. | |||
==Algebraic Geometry Mailing List== | ==Algebraic Geometry Mailing List== | ||
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|- | |- | ||
|March 18 | |March 18 | ||
| | |[https://www.math.ksu.edu/~fedorov/ Roman Fedorov] (Kansas State) | ||
| | |Motivic classes of moduli spaces of vector bundles with connections | ||
| | |Dima | ||
|- | |- | ||
|March 25 | |March 25 | ||
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|- | |- | ||
|April 1 | |April 1 | ||
| | | | ||
| | | | ||
| | |||
|- | |- | ||
|April 8 | |April 8 | ||
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|- | |- | ||
|April 15 | |April 15 | ||
| | |[http://www.math.wisc.edu/~djbruce/ DJ Bruce] (Wisconsin) | ||
| | |Noether Normalization in Families | ||
| | |Local | ||
|- | |- | ||
|April 22 | |April 22 | ||
| | |No seminar | ||
| | | | ||
| | | | ||
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|April 29 | |April 29 | ||
|[http://people.math.osu.edu/anderson.2804/ David Anderson] (Ohio State) | |[http://people.math.osu.edu/anderson.2804/ David Anderson] (Ohio State) | ||
| | |Old and new formulas for degeneracy loci | ||
|Steven | |Steven | ||
|- | |- | ||
|May 6 | |May 6 | ||
| | |[http://www.math.wisc.edu/~arinkin/ Dima Arinkin] (Wisconsin) | ||
| | |Geometric approach to linear ODEs | ||
| | |Local | ||
|} | |} | ||
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I will explain how to compute the characters of the GL-equivariant D-modules on a complex vector space of matrices (general, symmetric, or skew-symmetric), and describe some applications to calculations of local cohomology and Bernstein-Sato polynomials. | I will explain how to compute the characters of the GL-equivariant D-modules on a complex vector space of matrices (general, symmetric, or skew-symmetric), and describe some applications to calculations of local cohomology and Bernstein-Sato polynomials. | ||
===Eric Ramos=== | |||
The Local Cohomology of FI-modules | |||
Much of the work in homological invariants of FI-modules has been concerned with properties of certain right exact functors. One reason for this is that the category of finitely generated FI-modules over a Noetherian ring very rarely has sufficiently many injectives. In this talk we consider the (left exact) torsion functor on the category of finitely generated FI-modules, and show that its derived functors exist. Properties of these derived functors, which we call the local cohomology functors, can be used in reproving well known theorems relating to the depth, regularity, and stable range of a module. We will also see that various facts from the local cohomology of modules over a polynomial ring have analogs in our context. This is joint work with Liping Li. | |||
=== Roman Fedorov === | |||
Motivic classes of moduli spaces of vector bundles with connections | |||
For an Artin stack of finite type, one can define its motivic | |||
class in a certain localization of the K-ring of varieties. We | |||
calculate the motivic class of a moduli stack of vector bundles with | |||
connections on a smooth projective curve. We also discuss | |||
generalizations to parabolic bundles with singular connections. This | |||
is a joint project with Alexander Soibelman and Yan Soibelman. | |||
=== Vasily Dolgushev=== | === Vasily Dolgushev=== | ||
Line 131: | Line 146: | ||
In the paper “Formal noncommutative symplectic geometry”, Maxim Kontsevich introduced three versions of cochain complexes GCCom, GCLie and GCAs “assembled from” graphs with some additional structures. The graph complex GCCom (resp. GCLie, GCAs) is related to the operad Com (resp. Lie, As) governing commutative (resp. Lie, associative) algebras. Although the graphs complexes GCCom, GCLie and GCAs (and their generalizations) are easy to define, it is hard to get very much information about their cohomology spaces. In my talk, I will describe the links between these graph complexes (and their modifications) to the cohomology of the moduli spaces of curves, the group of outer automorphisms Out(Fr) of the free group Fr on r generators, the absolute Galois group Gal(Qbar/Q) of rationals, finite type invariants of tangles, and the homotopy groups of embedding spaces. | In the paper “Formal noncommutative symplectic geometry”, Maxim Kontsevich introduced three versions of cochain complexes GCCom, GCLie and GCAs “assembled from” graphs with some additional structures. The graph complex GCCom (resp. GCLie, GCAs) is related to the operad Com (resp. Lie, As) governing commutative (resp. Lie, associative) algebras. Although the graphs complexes GCCom, GCLie and GCAs (and their generalizations) are easy to define, it is hard to get very much information about their cohomology spaces. In my talk, I will describe the links between these graph complexes (and their modifications) to the cohomology of the moduli spaces of curves, the group of outer automorphisms Out(Fr) of the free group Fr on r generators, the absolute Galois group Gal(Qbar/Q) of rationals, finite type invariants of tangles, and the homotopy groups of embedding spaces. | ||
=== | ===DJ Bruce=== | ||
The | Noether Normalization in Families | ||
Classically, Noether normalization says that any projective (resp. affine) variety of dimension n over a field admits a finite surjective morphism to P^n (resp. A^n). I will discuss whether we can generalize such theorems to other bases like Z, C[t], etc. This is based on joint work with Daniel Erman appearing in [http://arxiv.org/abs/1604.01704]. | |||
===David Anderson=== | |||
Old and new formulas for degeneracy loci | |||
A very old problem asks for the degree of a variety defined by rank conditions on matrices. The story of the modern approach begins in the 1970’s, when Kempf and Laksov proved that the degeneracy locus for a map of vector bundles is given by a certain determinant in their Chern classes. Since then, many variations have been studied — for example, when the vector bundles are equipped with a symplectic or quadratic form, the formulas become Pfaffians. I will describe recent extensions of these results — beyond determinants and Pfaffians, and beyond ordinary cohomology — including my joint work with W. Fulton, as well as work of several others. | |||
===Dima Arinkin=== | |||
Geometric approach to linear ODEs | |||
There is a classical correspondence between systems of n linear ordinary differential equations (ODEs) of order one and linear ODEs of order n. (The correspondence may be viewed as a kind of canonical normal form for systems of ODEs.) The correspondence can be restated geometrically: | |||
given a Riemann surface C, a vector bundle E on C, and a connection <math>\nabla</math> on E, it is possible to find a rational basis of E such that | |||
<math>\nabla</math> is in the canonical normal form. | |||
All of the above objects have a version for arbitrary semisimple Lie group G (with the case of systems of ODEs corresponding to G=GL(n)): we can consider differential operators whose `matrices' are in the Lie algebra of G, and then try to `change the basis' so that the `matrix' is in the `canonical normal form'. However, the statement turns out to be significantly harder. In my talk, I will show how the geometric approach can be used to prove the claim for any G. | |||
The talk is based on my paper [http://arxiv.org/abs/1602.08989 Irreducible connections admit generic oper structures]. |
Latest revision as of 17:34, 17 August 2016
The seminar meets on Fridays at 2:25 pm in Van Vleck B113.
Here is the schedule for the previous semester and for this semester.
Algebraic Geometry Mailing List
- Please join the AGS Mailing List to hear about upcoming seminars, lunches, and other algebraic geometry events in the department (it is possible you must be on a math department computer to use this link).
Spring 2016 Schedule
date | speaker | title | host(s) |
---|---|---|---|
January 22 | Tim Ryan (UIC) | Moduli Spaces of Sheaves on \PP^1 \times \PP^1 | Daniel |
January 29 | Local | ||
February 5 | Botong Wang (Wisconsin) | Topological Methods in Algebraic Statistics | Local |
February 12 | Jay Yang (Wisconsin) | Random Toric Surfaces | Local |
February 19 | Daniel Erman (Wisconsin) | Supernatural Analogues of Beilinson Monads | Local |
February 26 | TBD | ||
March 4 | Claudiu Raicu (Notre Dame) | Characters of equivariant D-modules on spaces of matrices | Steven |
March 11 | Eric Ramos (Wisconsin) | Local Cohomology of FI-modules | Local |
March 18 | Roman Fedorov (Kansas State) | Motivic classes of moduli spaces of vector bundles with connections | Dima |
March 25 | Vasily Dolgushev (Temple) | The Intricate Maze of Graph Complexes | Andrei |
April 1 | |||
April 8 | TBD | ||
April 15 | DJ Bruce (Wisconsin) | Noether Normalization in Families | Local |
April 22 | No seminar | ||
April 29 | David Anderson (Ohio State) | Old and new formulas for degeneracy loci | Steven |
May 6 | Dima Arinkin (Wisconsin) | Geometric approach to linear ODEs | Local |
Abstracts
Tim Ryan
Moduli Spaces of Sheaves on \PP^1 \times \PP^1
In this talk, after reviewing the basic properties of moduli spaces of sheaves on P^1 x P^1, I will show that they are $\mathbb{Q}$-factorial Mori Dream Spaces and explain a method for computing their effective cones. My method is based on the generalized Beilinson spectral sequence, Bridgeland stability and moduli spaces of Kronecker modules.
Botong Wang
Topological Methods in Algebraic Statistics
In this talk, I will give a survey on the relation between maximum likelihood degree of an algebraic variety and it Euler characteristics. Maximam likelihood degree is an important constant in algebraic statistics, which measures the complexity of maximum likelihood estimation. For a smooth very affine variety, June Huh showed that, up to a sign, its maximum likelihood degree is equal to its Euler characteristics. I will present a generalization of Huh's result to singular varieties, using Kashiwara's index theorem. I will also talk about how to compute the maximum likelihood degree of rank 2 matrices as an application.
Daniel Erman
Supernatural analogues of Beilinson monads
First I will discuss Beilinson's resolution of the diagonal and some of the applications of that construction including the notion of a Beilinson monad. Then I will discuss new work, joint with Steven Sam, where we use supernatural bundles to build GL-equivariant resolutions supported on the diagonal of P^n x P^n, in a way that extends Beilinson's resolution of the diagonal. I will discuss some applications of these new constructions.
Claudiu Raicu
Characters of equivariant D-modules on spaces of matrices
I will explain how to compute the characters of the GL-equivariant D-modules on a complex vector space of matrices (general, symmetric, or skew-symmetric), and describe some applications to calculations of local cohomology and Bernstein-Sato polynomials.
Eric Ramos
The Local Cohomology of FI-modules
Much of the work in homological invariants of FI-modules has been concerned with properties of certain right exact functors. One reason for this is that the category of finitely generated FI-modules over a Noetherian ring very rarely has sufficiently many injectives. In this talk we consider the (left exact) torsion functor on the category of finitely generated FI-modules, and show that its derived functors exist. Properties of these derived functors, which we call the local cohomology functors, can be used in reproving well known theorems relating to the depth, regularity, and stable range of a module. We will also see that various facts from the local cohomology of modules over a polynomial ring have analogs in our context. This is joint work with Liping Li.
Roman Fedorov
Motivic classes of moduli spaces of vector bundles with connections
For an Artin stack of finite type, one can define its motivic class in a certain localization of the K-ring of varieties. We calculate the motivic class of a moduli stack of vector bundles with connections on a smooth projective curve. We also discuss generalizations to parabolic bundles with singular connections. This is a joint project with Alexander Soibelman and Yan Soibelman.
Vasily Dolgushev
The Intricate Maze of Graph Complexes
In the paper “Formal noncommutative symplectic geometry”, Maxim Kontsevich introduced three versions of cochain complexes GCCom, GCLie and GCAs “assembled from” graphs with some additional structures. The graph complex GCCom (resp. GCLie, GCAs) is related to the operad Com (resp. Lie, As) governing commutative (resp. Lie, associative) algebras. Although the graphs complexes GCCom, GCLie and GCAs (and their generalizations) are easy to define, it is hard to get very much information about their cohomology spaces. In my talk, I will describe the links between these graph complexes (and their modifications) to the cohomology of the moduli spaces of curves, the group of outer automorphisms Out(Fr) of the free group Fr on r generators, the absolute Galois group Gal(Qbar/Q) of rationals, finite type invariants of tangles, and the homotopy groups of embedding spaces.
DJ Bruce
Noether Normalization in Families Classically, Noether normalization says that any projective (resp. affine) variety of dimension n over a field admits a finite surjective morphism to P^n (resp. A^n). I will discuss whether we can generalize such theorems to other bases like Z, C[t], etc. This is based on joint work with Daniel Erman appearing in [1].
David Anderson
Old and new formulas for degeneracy loci
A very old problem asks for the degree of a variety defined by rank conditions on matrices. The story of the modern approach begins in the 1970’s, when Kempf and Laksov proved that the degeneracy locus for a map of vector bundles is given by a certain determinant in their Chern classes. Since then, many variations have been studied — for example, when the vector bundles are equipped with a symplectic or quadratic form, the formulas become Pfaffians. I will describe recent extensions of these results — beyond determinants and Pfaffians, and beyond ordinary cohomology — including my joint work with W. Fulton, as well as work of several others.
Dima Arinkin
Geometric approach to linear ODEs
There is a classical correspondence between systems of n linear ordinary differential equations (ODEs) of order one and linear ODEs of order n. (The correspondence may be viewed as a kind of canonical normal form for systems of ODEs.) The correspondence can be restated geometrically: given a Riemann surface C, a vector bundle E on C, and a connection [math]\displaystyle{ \nabla }[/math] on E, it is possible to find a rational basis of E such that [math]\displaystyle{ \nabla }[/math] is in the canonical normal form.
All of the above objects have a version for arbitrary semisimple Lie group G (with the case of systems of ODEs corresponding to G=GL(n)): we can consider differential operators whose `matrices' are in the Lie algebra of G, and then try to `change the basis' so that the `matrix' is in the `canonical normal form'. However, the statement turns out to be significantly harder. In my talk, I will show how the geometric approach can be used to prove the claim for any G.
The talk is based on my paper Irreducible connections admit generic oper structures.