Galois descent of splendid Rickard equivalences for blocks of $p$-nilpotent groups

Sam K. Miller

Galois descent of splendid Rickard equivalences for blocks of $p$-nilpotent groups

Sam K. Miller

Abstract

We strengthen the results of Boltje and Yilmaz regarding the Galois descent of equivalences of blocks of $p$-nilpotent groups and a result of Kessar and Linckelmann regarding Galois descent of splendid Rickard equivalences for blocks with compatible Galois stabilizers. A more general descent criteria for chain complexes is proven along the way, which requires the adaptation of a theorem of Reiner for chain complexes. This verifies Kessar and Linckelmann's refinement of Broué's abelian defect group conjecture for blocks of $p$-nilpotent groups with abelian Sylow $p$-subgroup.

Galois descent of splendid Rickard equivalences for blocks of $p$-nilpotent groups

Abstract

We strengthen the results of Boltje and Yilmaz regarding the Galois descent of equivalences of blocks of

-nilpotent groups and a result of Kessar and Linckelmann regarding Galois descent of splendid Rickard equivalences for blocks with compatible Galois stabilizers. A more general descent criteria for chain complexes is proven along the way, which requires the adaptation of a theorem of Reiner for chain complexes. This verifies Kessar and Linckelmann's refinement of Broué's abelian defect group conjecture for blocks of

-nilpotent groups with abelian Sylow

-subgroup.

Paper Structure (9 theorems, 20 equations, 1 figure)

This paper contains 9 theorems, 20 equations, 1 figure.

Key Result

Theorem 1

(BY22 for splendid Rickard equivalences) Let $G$ be a $p$-nilpotent group with abelian Sylow $p$-subgroup and let $\tilde{b}$ be a block idempotent of $\mathbb{F}_pG$. Then there exists a splendid Rickard equivalence between $\mathbb{F}_pG\tilde{b}$ and its Brauer correspondent block algebra. In par

Figures (1)

Figure 1: The lattice of subgroups and blocks for a $p$-nilpotent group $G$.

Theorems & Definitions (16)

Theorem 1
Theorem 2
Proposition 3
Lemma 4
proof
Proposition 5
proof
Theorem 6
proof
Lemma 7
...and 6 more