Difference between revisions of "Classification by p-group"

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(Q8 references)
(Defect groups of order 27)
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{| role="presentation" class="wikitable mw-collapsible mw-collapsed"
 
{| role="presentation" class="wikitable mw-collapsible mw-collapsed"
| <strong><math>3 \leq |D| \leq 9</math> &nbsp;</strong>
+
| <strong><math>3 \leq |D| \leq 27</math> &nbsp;</strong>
 
|-
 
|-
 
! scope="col"| <math>|D|</math>
 
! scope="col"| <math>|D|</math>
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|9 || [[C9|1]] ||[[C9|<math>C_9</math>]] || 3(3) || <math>\mathcal{O}</math> || <math>\mathcal{O}</math> || ||  
 
|9 || [[C9|1]] ||[[C9|<math>C_9</math>]] || 3(3) || <math>\mathcal{O}</math> || <math>\mathcal{O}</math> || ||  
 
|-
 
|-
|9 || [[C3xC3|2]] || [[C3xC3|<math>C_3 \times C_3</math>]] || || || || ||  
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|9 || [[C3xC3|2]] || [[C3xC3|<math>C_3 \times C_3</math>]] || || || || ||
 +
|-
 +
|27 || [[C27|1]] || [[C27|<math>C_{27}</math>]] || || || || ||
 +
|-
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|27 || [[C9xC3|2]] || [[C9xC3|<math>C_9 \times C_3</math>]] || || || || ||
 +
|-
 +
|27 || [[3_+^3|3]] || [[3_+^3|<math>3_+^{1+2}</math>]] || || || || ||
 +
|-
 +
|27 || [[3_-^3|4]] || [[3_-^3|<math>3_-^{1+2}</math>]] || || || || ||
 +
|-
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|27 || [[C3xC3xC3|5]] || [[C3xC3xC3|<math>C_3 \times C_3 \times C_3</math>]] || || || || ||
 
|}
 
|}
  

Revision as of 15:46, 5 September 2018

Classification of Morita equivalences for blocks with a given defect group

On this page we list classifications of Morita equivalence classes for each isomorphism class of p-groups in turn. Generic classifications for classes of p-groups can be found here.

We use the following notation for Morita equivalence classes of blocks of finite groups with respect to an algebraically closed field k.

[math]M(x,y,z)[/math] is a class consisting of blocks with defect groups of order x, with a representative having defect group SmallGroup(x,y) in GAP/MAGMA labelling. It is the z-th such class.

Note that it is not known that the isomorphism class of a defect group is a Morita invariant, so it could be that [math]M(x,y1,z1)=M(x,y2,z2)[/math] for some [math](y1,z1) \neq (y2,z2)[/math].

Also, at present there is no known example of a k-Morita equivalence class of blocks which splits into more than one Morita equivalence class with respect to a complete discrete valuation ring. If such an example arises, then we will bring in more notation for classes with respect to the d.v.r.

Blocks of defect zero

Blocks for [math] p=2 [/math]

Blocks for [math]p=3[/math]

Blocks for [math]p=5[/math]

Blocks for [math]p\geq 7[/math]