Geometry and Topology

Speaker: Alexander Neshitov (Western)

"Fibrant resolutions of motivic Thom spectra"

Time: 15:30

Room: MC 107

This is a joint work with G.Garkusha. In the talk I will discuss the construction of fibrant replacements for spectra consisting of Thom spaces (suspension spectra of varieties and algebraic cobordism MGL being the motivating examples) that uses the theory of framed correspondences. As a consequence we get a description of the infinite loop space of MGL in terms of Hilbert schemes.

Colloquium

Speaker: Matthias Franz (Western)

"The cohomology rings of homogeneous spaces"

Time: 15:30

Room: MC 108

Let $G$ be a compact connected Lie group and $K$ a closed connected subgroup. In 1950 Cartan determined the real cohomology ring of the homogeneous space $G/K$. The formula can be written as a torsion product involving the cohomologies of the classifying spaces BG and BK, which are polynomial algebras. Around 1970 this result was extended to other coefficients through work of Baum, Gugenheim-May, Husemoller-Moore-Stasheff, Munkholm and Wolf. However, the isomorphism was only shown to be additive in this case. I will present a recent result saying that the isomorphism is in fact multiplicative and natural in the pair $(G,K)$, provided that 2 is invertible in the coefficient ring. I will also discuss the main new ideas of the proof, which involve homotopy Gerstenhaber algebras.

Algebraic Geometry

Speaker: Ajneet Dhillon (Western)

"K-theory : organisational meeting"

Time: 15:30

Room: WSC 187

This is to just get started. We will assign topics and speakers. We will also recall some results from last year.

Geometry and Topology

Speaker: Apurva Nakade (Western)

"Manifold Calculus and Gromov's h-principle"

Time: 15:30

Room: MC 107

Embedding calculus is a homotopy theoretic technique for studying embedding spaces of manifolds. I will explain the general theory of embedding calculus and how the analytic approximation of the Lagrangian embeddings functor is the Totally Real embeddings functor, using Gromov's $h$-principle. Most of my talk will be homotopy theoretic and accessible to graduate students.

Colloquium

Speaker: Hristo Sendov (Western)

"Stronger Rolle's Theorem for Complex Polynomials"

Time: 15:30

Room: MC 108

Every Calculus student is familiar with the classical Rolle's theorem stating that if a real polynomial $p$ satisfies $p(-1) = p(1)$, then it has a critical point in $(-1, 1)$. In 1934, L. Tschakaloff strengthened this result by finding a {\it minimal} interval, contained in $(-1,1)$, that holds a critical point of every real polynomial with $p(-1) = p(1)$, up to a fixed degree. In 1936, he expressed a desire to find an analogue of his result for complex polynomials.

This talk will present the following Rolle's theorem for complex polynomials. If $p(z)$ is a complex polynomial of degree $n\geq 5$, satisfying $p(-i)=p(i)$, then there is at least one critical point of $p$ in the union $D[-c;r] \cup D[c;r]$ of two closed disks with centres $-c, c$ and radius $r$, where $$ c= \cot (2\pi/n),\;\;\; r=1/ \sin (2\pi/n). $$ If $n=3$, then the closed disk $D[0; 1/\sqrt{3}]$ has this property; and if $n=4$ then the union of the closed disks $D[-1/3; 2/3] \cup D[1/3; 2/3]$ has this property. In the last two cases, the domains are minimal, with respect to inclusion, having this property.

This theorem is stronger than any other known Rolle's Theorem for complex polynomials of any degree. A minimal Rolle's domain are found for polynomials of degree $3$ and $4$, answering Tschakaloff's question.

This is a joint work with Blagovest Sendov from the Bulgarian Academy of Sciences.

Algebraic Geometry

Speaker: Nicole Lemire (Western)

"Lambda operations"

Time: 15:30

Room: WSC 187

Geometry and Combinatorics

Speaker: Avi Steiner (Western)

"Intro to GKZ systems I"

Time: 15:30

Room: MC 108

TBA

Quantum Geometry

Speaker: Masoud Khalkhali (Western)

"Combinatorics of Feynman diagrams and quantum field theory II"

Time: 11:00

Room: MC 108

Geometry and Topology

Speaker: Nikon Kurnosov (University of Georgia)

"Algebra and geometry of hyperkahler manifolds"

Time: 15:30

Room: MC 107

Hyperkahler manifolds are complex manifolds with a trivial canonical class. They are interesting both for algebraic and differential geometers. I would like to discuss some compact examples, and their geometry as well as the structure of their cohomology ring.