If a group G has order p^n, show any subgroup of order p^n-1 is normal

demonelite123
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If a group G has order p^n, show that any subgroup of order p^{n-1} is normal in G.

i have no idea how to start this. i know that to show that a subgroup N is normal in G, i need that gNg^{-1} = N. so i start with any subgroup N of order p^{n-1} but i have no idea how to continue.

this problem appears in the section before the sylow theorems are introduced so i can't use them. i know that for p-groups, the center is nontrivial and has prime power order. also in this same section, Cauchy's theorem was introduced which says if p divides the order of a group then that group has an element of order p. these concepts were introduced fairly recently to me so this may be why i am having trouble.

can someone give me a hint or 2 to continue? thanks
 
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Let H be your subgroup of order pn-1. Consider the action of G on the set X=\{Hg~\vert~g\in G\} by multiplication on the right. This determines a group morphism

G\rightarrow Sym(X)

with kernel N. The idea is to prove that N=H. Prove this in the following steps:

1) N\subseteq H
2) [G:N]=p[H:N]
3) G/N is a subgroup of Sym(X), so [G:N] divides p!
4) [H:N]=1.
 
don't you actually want a left-action, so that you have a homomorphism, rather than an anti-homomorphism? i mean, usually mappings are written on the left, so we have x(gH), rather than (Hg)x (or Hg.x, if you prefer). it's a small (minor) issue, but usually actions are taken to be left-actions, because of the way we normally compose functions.
 
Deveno said:
don't you actually want a left-action, so that you have a homomorphism, rather than an anti-homomorphism? i mean, usually mappings are written on the left, so we have x(gH), rather than (Hg)x (or Hg.x, if you prefer). it's a small (minor) issue, but usually actions are taken to be left-actions, because of the way we normally compose functions.

It would indeed make more sense. But I'm so used to right actions and right cosets that I can't help it :biggrin:
 

Thread 'Prove that the integral is equal to ##\pi^2/8##'

Prove $$\int\limits_0^{\sqrt2/4}\frac{1}{\sqrt{x-x^2}}\arcsin\sqrt{\frac{(x-1)\left(x-1+x\sqrt{9-16x}\right)}{1-2x}} \, \mathrm dx = \frac{\pi^2}{8}.$$ Let $$I = \int\limits_0^{\sqrt 2 / 4}\frac{1}{\sqrt{x-x^2}}\arcsin\sqrt{\frac{(x-1)\left(x-1+x\sqrt{9-16x}\right)}{1-2x}} \, \mathrm dx. \tag{1}$$ The representation integral of ##\arcsin## is $$\arcsin u = \int\limits_{0}^{1} \frac{\mathrm dt}{\sqrt{1-t^2}}, \qquad 0 \leqslant u \leqslant 1.$$ Plugging identity above into ##(1)## with ##u...
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