Quivers and quantum algebras
Frequency
Only this year
Summary
We will survey state of the art research on quantum algebras that arise from quivers. Our guiding examples will be quantum loop groups associated to symmetric Cartan matrices, but we will also seek to understand the general theory, where many open results remain.
Content
Fix a finite set I, which generalizes the set of simple roots of a Dynkin diagram. For any collection of Laurent polynomials zeta_{ij}(x) with i,j running over the set I, we may define a so-called shuffle algebra, following ideas of Feigin-Odesskii. The definition might seem a bit contrived at first, but we will observe that particular cases of this construction give rise to very interesting quantum algebras, such as
- quantum loop groups associated to finite type Cartan matrices
- cohomological (or more appropriately, K-theoretic) Hall algebras of quivers
- BPS algebras arising from quantum mechanics on a toric Calabi-Yau threefold
and the list goes on. The principle that we will repeatedly encounter is that the shuflle algebra gives a great computational tool to study the above algebraic objects. We will delve in the detailed study of shuffle algebras, with the concrete goal of obtaining a definition of quantum loop groups associated to any symmetric Cartan matrix. As challenging as this task will turn out to be, it pales in comparison to the (still unsolved) task of completely describing shuffle algebras for all possible collections of Laurent polynomials zeta_{ij}(x). One of the main goals of our course will be to provide interested mathematicians with tools they might need to tackle this difficult question.
Keywords
Quantum algebras, Kac-Moody Lie algebras, shuffle algebras
Learning Prerequisites
Recommended courses
Required: MATH-311 and one of MATH-319, 429 or 492
Learning Outcomes
By the end of the course, the student must be able to:
- Define the interplay between quivers and quantum algebras
- Perform he main computations (and prove the main theorems) in specific examples
In the programs
- Exam form: Project report (session free)
- Subject examined: Quivers and quantum algebras
- Lecture: 22 Hour(s)
- Practical work: 12 Hour(s)
- Type: optional