Algebra Seminar

Speaker: Franz-Viktor Kuhlmann (Saskatchewan)

"Notes on tame and extremal valued fields"

Time: 14:30

Room: MC 107

In the year 2003 I first heard of the notion of extremal valued fields when Yuri Ershov gave a talk at a conference in Tehran. He proved that algebraically complete discretely valued fields are extremal. However, the proof contained a mistake, and it turned out in 2009 through an observation by Sergej Starchenko that Ershov's original definition leads to all extremal fields being algebraically closed. In joint work with Salih Durhan (formerly Azgin) and Florian Pop, we chose a more appropriate definition and then characterized extremal valued fields in several important cases.

We call a valued field $(K,v)$ extremal if for all natural numbers $n$ and all polynomials $f$ in $K[X_1,...,X_n]$, the set {$f(a_1,...,a_n) | a_1,...,a_n$ in the valuation ring} has a maximum (which is allowed to be infinity, which is the case if $f$ has a zero in the valuation ring). This is such a natural property of valued fields that it is in fact surprising that it has apparently not been studied much earlier. It is also an important property because Ershov's original statement is true under the revised definition, which implies that in particular all Laurent Series Fields over finite fields are extremal. As it is a deep open problem whether these fields have a decidable elementary theory and as we are therefore looking for complete recursive axiomatizations, it is important to know the elementary properties of them well. That these fields are extremal seems to be an important ingredient in the determination of their structure theory, which in turn is an essential tool in the proof of model theoretic properties.

Further, it came to us as a surprise that extremality is closely connected with Pop's notion of "large fields". Also the notion of tame valued fields plays a crucial role in the characterization of extremal fields; both large and tame valued fields have the right model theoretic properties. A valued field $K$ with algebraic closure $K^{ac}$ is tame if it is henselian and the ramification field of the extension $K^{ac}|K$ coincides with the algebraic closure.

In my talk I will introduce the above notions, try to explain their meaning and importance also to the non-expert, and discuss in detail what is known about extremal fields and how the properties of large and of tame fields appear in the proofs of the characterizations we give. I will also discuss the connections with additive polynomials in the case of positive characteristic. Finally, I will present some challenging open problems whose solution may have an impact on the above mentioned problem for Laurent Series Fields over finite fields.

Dept Oral Exam

Speaker: Youlong Yan (Western)

"Tilting Sheaves on Brauer-Severi Schemes and Arithmetic Toric Varieties"

Time: 13:00

Room: MC 107

The derived category of coherent sheaves on a smooth projective variety is an important object of study in algebraic geometry. One import device relevant for this study is the notion of tilting sheaf. We first show the existence of tilting bundles on some Brauer-Severi schemes, and as an application, we construct tilting bundles on some arithmetic toric varieties.

Index Theory Seminar

Speaker: Matthias Franz and Sean Fitzpatrick (Western)

"The Weyl and Kirillov character formulas"

Time: 12:00

Room: MC 107

This will be a two-part presentation on character formulas for representations of compact Lie groups. In the first part, Matthias Franz will present Weyl's formula. In the second part, Sean Fitzpatrick will present Kirillov's formula.

Homotopy Theory

Speaker: Dan Christensen (Western)

"An introduction to Type Theory"

Time: 14:00

Room: MC 107

The theory of types was introduced by Bertrand Russell as a foundation for mathematics that avoids Russell's paradox. A more refined theory was introduced by Martin-Löf in 1972, and this theory is the basis for much modern research on type theory. It was later realized that type theory also has an intrinsically homotopical interpretation, and describing this will be the long term goal of the seminar series.

In this talk, I will give an introduction to (non-homotopical) type theory, explaining how types can be thought of either as sets or as propositions, and give examples of how to do mathematics using type theory. I will also show how type theory is used in the proof assistant Coq, which has been used to formalize many non-trivial results. I will also discuss the intuitionistic logic that arises in type theory.

Homotopy Theory

Speaker: Martin Frankland (Western)

"Inductive types and identity types"

Time: 14:00

Room: MC 107

We will discuss inductive types, which are defined using constructors. Examples include the unit type, sum types, and product types introduced last week. Then we will discuss proofs by induction in the context of inductive types. Lastly, we will discuss identity types, which will play the role of path spaces in the homotopical interpretation of type theory.

Homotopy Theory

Speaker: Hugo Bacard (Western)

"Identity types and higher groupoids"

Time: 14:00

Room: MC 107

After recalling the construction of identity types as inductive types, we will use the induction principle to prove basic facts about identity types. Throughout the talk, we will pursue the analogy between identity types and path spaces. We will illustrate how iterated identity types form a structure reminiscent of the low-dimensional data of an $\infty$-groupoid.

Noncommutative Geometry

Speaker: Shane Farnsworth (Perimeter Institute)

"Building particle models as non-commutative geometries"

Time: 14:30

Room: MC 108

Non-commutative differential geometry (NCG) generalizes Riemannian geometry and provides a framework within which many interesting Yang-Mills theories coupled to Einstein-Hilbert gravity may be elegantly reformulated. One physical value of this reformulation is that it is subject to a number of geometric constraints which severely limit the allowable physical models that may be constructed. Surprisingly the standard model of particle physics coupled to Einstein-Hilbert gravity is one such model, and so it might be possible to use the rigidity of the NCG formalism to single out possible extensions to explore. In this talk I will provide a first introduction to the NCG standard particle model from the perspective of a particle model builder, focusing on the construction itself rather than its phenomenology.

Algebra Seminar

Speaker: Danny Neftin (Ann Arbor)

"Galois subfields of tame division algebras"

Time: 11:00

Room: MC 107

It is a central problem concerning division algebras to determine which finite dimensional division algebras are crossed products, that is, admit a maximal subfield that is Galois over the center. We shall discuss a simple crossed product criterion for tamely ramified valued division algebras, and apply it to describe the location of noncrossed products in the Brauer group of Henselian fields.

Based on joint work with Timo Hanke and Adrian Wadsworth.

Homotopy Theory

Speaker: Mike Misamore (Western)

"Operations on paths and type equivalence"

Time: 14:00

Room: MC 107

We will continue the discussion of path induction, and use it to produce further operations on paths, such as applying functions to paths, and the transport between fibers. Then, we will discuss the notions of homotopy between functions and equivalence between types.

Colloquium

Speaker: Chung Pang Mok (McMaster)

"An introduction to the Langlands program, through classical examples"

Time: 15:30

Room: MC 107

We will give an introduction to the ideas of the Langlands program, through the classical problems in algebraic number theory, elliptic curves and L-functions.

Noncommutative Geometry

Speaker: Chung Pang Mok (McMaster)

"Speculations on the future possibilities of the Langlands program"

Time: 13:00

Room: MC 108

In this talk we give a selected overview of the major developments of the Langlands program so far, and suggest some questions as speculations on the future possibilities of the program.