Difference between revisions of "C2xC2"

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== Blocks with defect group <math>C_2 \times C_2</math> ==
 
== Blocks with defect group <math>C_2 \times C_2</math> ==
  
These are blocks were first classified over <math>k</math> by Erdmann (see [Er82]). Linckelmann classified them over <math>\mathcal{O}</math> in [Li94], in which he also showed that the source algebras lie within three infinite families. In [CEKL11] the CFSG was used to show that only one source algebra can occur for each Morita equivalence class.
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These are blocks are examples of [[Tame blocks|tame blocks]] and were first classified over <math>k</math> by Erdmann (see [Er82]). Linckelmann classified them over <math>\mathcal{O}</math> in [Li94], in which he also showed that the source algebras lie within three infinite families. In [CEKL11] the CFSG was used to show that only one source algebra can occur for each Morita equivalence class.
  
 
There are three <math>\mathcal{O}</math>-Morita equivalence classes.
 
There are three <math>\mathcal{O}</math>-Morita equivalence classes.

Revision as of 12:53, 28 August 2018

Blocks with defect group [math]C_2 \times C_2[/math]

These are blocks are examples of tame blocks and were first classified over [math]k[/math] by Erdmann (see [Er82]). Linckelmann classified them over [math]\mathcal{O}[/math] in [Li94], in which he also showed that the source algebras lie within three infinite families. In [CEKL11] the CFSG was used to show that only one source algebra can occur for each Morita equivalence class.

There are three [math]\mathcal{O}[/math]-Morita equivalence classes.

Class Representative [math]k(B)[/math] [math]l(B)[/math] Inertial quotients [math]{\rm Pic}_\mathcal{O}(B)[/math] [math]{\rm Pic}_k(B)[/math] [math]{\rm mf_\mathcal{O}(B)}[/math] [math]{\rm mf_k(B)}[/math] Notes
[math]M(4,2,1)[/math] [math]k(C_2 \times C_2)[/math] 4 1 [math]1[/math] [math](C_2 \times C_2):S_3[/math] [math](k \times k):GL_2(k)[/math] 1 1
[math]M(4,2,2)[/math] [math]kA_4[/math] 4 3 [math]C_3[/math] [math]S_3[/math] [math](k^* \times k^* \times C_3):C_2[/math] 1 1
[math]M(4,2,3)[/math] [math]B_0(kA_5)[/math] 4 3 [math]C_3[/math] [math]C_2[/math] [math](k^* \times k^*):C_2[/math] 1 1