If a,b are in G, Prove that the order of aba-1 is the order of b

Let G be a group of order 4. Prove that either G is generated by a...

Let G be a group of order 4. Prove that either G is generated by a single element or g^2 =1 for all g∈G.

Prove that if (G, ·) is a finite group of even order, then there always exists...

Prove that if (G, ·) is a finite group of even order, then there always exists an element g∈G such that g ≠ 1 and g2=1.

1(a) Suppose G is a group with p + 1 elements of order p , where...

1(a) Suppose G is a group with p + 1 elements of order p , where p is prime. Prove that G is not cyclic. (b) Suppose G is a group with order p, where p is prime. Prove that the order of every non-identity element in G is p.

Let G be a group. Prove that the relation a~b if b=gag^-1 for some g in...

Let G be a group. Prove that the relation a~b if b=gag^-1 for some g in G is an equivalence relation on G.

Let G be a group of order 4. Prove that either G is cyclic or it...

Let G be a group of order 4. Prove that either G is cyclic or it is isomorphic to the Klein 4-group V4 = {1,(12)(34),(13)(24),(14)(23)}.

prove that if G is a cyclic group of order n, then for all a in...

prove that if G is a cyclic group of order n, then for all a in G, a^n=e.

Let G be a graph or order n with independence number α(G) = 2. (a) Prove...

Let G be a graph or order n with independence number α(G) = 2. (a) Prove that if G is disconnected, then G contains K⌈ n/2 ⌉ as a subgraph. (b) Prove that if G is connected, then G contains a path (u, v, w) such that uw /∈ E(G) and every vertex in G − {u, v, w} is adjacent to either u or w (or both).

If A and B are matrices, A has size m × n, and the multiplication ABA...

If A and B are matrices, A has size m × n, and the multiplication ABA is defined, what can you say about the size of B, if anything?

Let G be a group of order p^3. Prove that either G is abelian or its...

Let G be a group of order p^3. Prove that either G is abelian or its center has exactly p elements.

Let G be a group (not necessarily an Abelian group) of order 425. Prove that G...

Let G be a group (not necessarily an Abelian group) of order 425. Prove that G must have an element of order 5. Note, Sylow Theorem is above us so we can't use it. We're up to Finite Orders. Thank you.