University of Cambridge > Talks.cam > Isaac Newton Institute Seminar Series > Lie theory in tensor categories with applications to modular representation theory

Lie theory in tensor categories with applications to modular representation theory

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  • UserPavel Etingof (Massachusetts Institute of Technology)
  • ClockTuesday 18 June 2024, 13:45-14:45
  • HouseExternal.

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TRHW02 - International Conference

Let G be a group and k an algebraically closed field of characteristic p>0. Let V be a finite dimensional representation of G over k. Then by the classical Krull-Schmidt theorem, the tensor power Vn can be uniquely decomposed into a direct sum of indecomposable representations. But we know very little about this decomposition, even for very small groups, such as G=(Z/2)3 for p=2 or G=(Z/3)2 for p=3. For example, what can we say about the number d_n(V) of such summands of dimension coprime to p? It is easy to show that there exists a finite limit d(V) of the n-th root of d_n(V), but what kind of number is it? For example, is it algebraic or transcendental? Until recently, there was no techniques to solve such questions (and in particular the same question about the sum of dimensions of these summands is still wide open). Remarkably, a new subject which may be called ``Lie theory in tensor categories” gives methods to show that d(V) is indeed an algebraic number, in fact one of a very specific form. Moreover, d is a character of the Green ring of G over k. Finally, d_n(V)>C(V)d(V)n, and we can give lower bounds for the constant C(V). In the talk I will explain what Lie theory in tensor categories is and how it can be applied to such problems. This is joint work with K. Coulembier and V. Ostrik.  

This talk is part of the Isaac Newton Institute Seminar Series series.

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