eBook ISBN:  9781470402976 
Product Code:  MEMO/149/706.E 
List Price:  $56.00 
MAA Member Price:  $50.40 
AMS Member Price:  $33.60 
eBook ISBN:  9781470402976 
Product Code:  MEMO/149/706.E 
List Price:  $56.00 
MAA Member Price:  $50.40 
AMS Member Price:  $33.60 

Book DetailsMemoirs of the American Mathematical SocietyVolume: 149; 2001; 112 ppMSC: Primary 20; 17
We give a selfcontained account of the results originating in the work of James and the second author in the 1980s relating the representation theory of \(GL_n(\mathbb{F}_q)\) over fields of characteristic coprime to \(q\) to the representation theory of “quantum \(GL_n\)” at roots of unity.
The new treatment allows us to extend the theory in several directions. First, we prove a precise functorial connection between the operations of tensor product in quantum \(GL_n\) and HarishChandra induction in finite \(GL_n\). This allows us to obtain a version of the recent Morita theorem of Cline, Parshall and Scott valid in addition for \(p\)singular classes.
From that we obtain simplified treatments of various basic known facts, such as the computation of decomposition numbers and blocks of \(GL_n(\mathbb{F}_q)\) from knowledge of the same for the quantum group, and the nondefining analogue of Steinberg's tensor product theorem. We also easily obtain a new double centralizer property between \(GL_n(\mathbb{F}_q)\) and quantum \(GL_n\), generalizing a result of Takeuchi.
Finally, we apply the theory to study the affine general linear group, following ideas of Zelevinsky in characteristic zero. We prove results that can be regarded as the modular analogues of Zelevinsky's and Thoma's branching rules. Using these, we obtain a new dimension formula for the irreducible crosscharacteristic representations of \(GL_n(\mathbb{F}_q)\), expressing their dimensions in terms of the characters of irreducible modules over the quantum group.
ReadershipGraduate students and research mathematicians interested in group theory and generalizations.

Table of Contents

Chapters

Introduction

1. Quantum linear groups and polynomial induction

2. Classical results on $GL_n$

3. Connecting $GL_n$ with quantum linear groups

4. Further connections and applications

5. The affine general linear group


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We give a selfcontained account of the results originating in the work of James and the second author in the 1980s relating the representation theory of \(GL_n(\mathbb{F}_q)\) over fields of characteristic coprime to \(q\) to the representation theory of “quantum \(GL_n\)” at roots of unity.
The new treatment allows us to extend the theory in several directions. First, we prove a precise functorial connection between the operations of tensor product in quantum \(GL_n\) and HarishChandra induction in finite \(GL_n\). This allows us to obtain a version of the recent Morita theorem of Cline, Parshall and Scott valid in addition for \(p\)singular classes.
From that we obtain simplified treatments of various basic known facts, such as the computation of decomposition numbers and blocks of \(GL_n(\mathbb{F}_q)\) from knowledge of the same for the quantum group, and the nondefining analogue of Steinberg's tensor product theorem. We also easily obtain a new double centralizer property between \(GL_n(\mathbb{F}_q)\) and quantum \(GL_n\), generalizing a result of Takeuchi.
Finally, we apply the theory to study the affine general linear group, following ideas of Zelevinsky in characteristic zero. We prove results that can be regarded as the modular analogues of Zelevinsky's and Thoma's branching rules. Using these, we obtain a new dimension formula for the irreducible crosscharacteristic representations of \(GL_n(\mathbb{F}_q)\), expressing their dimensions in terms of the characters of irreducible modules over the quantum group.
Graduate students and research mathematicians interested in group theory and generalizations.

Chapters

Introduction

1. Quantum linear groups and polynomial induction

2. Classical results on $GL_n$

3. Connecting $GL_n$ with quantum linear groups

4. Further connections and applications

5. The affine general linear group