Talk:Group theory: Difference between revisions

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I have written quite a bit on groups, and it would be nice to have someone help make it more readable. I think the "examples" section looks a bit daunting to the eye, but I'm not sure how to organize it any better. - Jared Grubb 23:59, 3 May 2007 (CDT)

A few thoughts

It's worth noting that groups can be roughly divided into finite and infinite groups. The infinite groups may be discrete groups closely related to the finite ones (e.g. ${\displaystyle \mathbb {Z} }$), Lie groups, or much more complex groups. Some obvious examples of finite groups are:

1. (finite) cyclic groups
2. direct sums of cyclic groups
3. the symmetric groups and alternatiing groups
4. the dihedral groups
5. the unit quaternions

Beyond that, there are the "classical" groups which are the analogues of linear Lie groups over finite fields (e.g., ${\displaystyle SL(n,\mathbb {F} _{q})}$ and ${\displaystyle PSL(n,\mathbb {F} _{q})}$.

This article should also talk about representations of groups (i.e., homomorphisms ${\displaystyle \rho :G\rightarrow GL(n,\mathbb {C} )}$), and this would be an excellent place to mention that there are exactly 5 regular polyhedra. The complete classification of finite simple groups needs to be mentioned, too.

Other topics from group theory should probably include:

1. group actions
2. group presentations by generators and relations
3. the isomorphism theorems
4. the "Burnside" lemma (which is not due to Burnside, but the name is traditional)
5. the Sylow theorems
6. applications to Galois theory
7. Klein's Erlangen program (characterization of geometries in terms of the group of symmetries of the geometry)

It might be reasonable to talk about applications of group theory to classical and quantum mechanics, too. Greg Woodhouse 04:40, 4 May 2007 (CDT)

Great suggestions! I've created Talk:Group theory/Brainstorming so we can brainstorm about this topic: what needs to be here, what should be at Group (mathematics). - Jared Grubb 10:40, 4 May 2007 (CDT)

Definitions needed

Interesting topic. So group theory is how it was proven that quintics can't be solved. (If I knew that before I'd forgotten it.)

This is where you lose me: A solvable group, or a soluble group, is a group that has a normal series whose quotient groups are all abelian. Definitions are needed for: "normal series", "quotient group", "alternating subgroup", "${\displaystyle A_{5}}$", "symmetric group".

In this sentence: A free group is a group in which every element of the group is a unique product, or string, of elements of some subset of the group. It needs to be clarified whether "unique" means that each element can be expressed as a product in only one way (up to use of the identity element, presumably), or whether it means that a given string can only represent one element (obviously true given the definition of binary operation) or perhaps that a given subset can only represent one element regardless of which order they're put into a string. --Catherine Woodgold 20:25, 5 May 2007 (CDT)

Those definitions are incomplete in this text, but I did that on purpose. I'm worried that if we put full-fledged definitions for every concept mentioned into this article, it will get large and unwieldy. So my intention is that the articles solvable group, quotient group, etc. would each discuss those concepts in greater detail, whereas this article just mentions enough to explain the role of each concept in group theory. What do you think of that? - Jared Grubb 10:45, 6 May 2007 (CDT)