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Problem Sets

Table of Contents

Problem Set 1 (due March 7)

  1. Let \(G\) be a finitely generated group with a finite generating set \(S\) and let \(\gamma\) be its growth function with respect to \(S\).
    • Show that for all \(a,b\ge 0\), \(\gamma(a+b)\le \gamma(a)\gamma(b)\).
    • Show that the growth exponent \(e_S=\lim_{n\to \infty}\frac{\log \gamma(n)}{n}\) exists.
  2. Let \(G\) be a group, let \(A,A'\) be subgroups of \(G\), and let \(\phi\from A\to A'\) be an isomorphism. For any \(g\in G\), let \(\phi^g\from A\to gA'g^{-1}\) be the map \(\phi^g(x)=gxg^{-1}\). Show that the HNN extensions \(G\ast_{\phi}\) and \(G\ast_{\phi^g}\) are isomorphic.
  3. Recall the description of \(BS(1,2)\) as an HNN extension \(BS(1,2)\cong \Z\ast_\phi\) from class, where \(\phi\from \Z\to 2\Z\) is multiplication by 2. Describe the corresponding tree \(T\) and the action of \(BS(1,2)\) on \(T\).
  4. (Britton's Lemma) Let $$H=G\ast_{\phi}=\langle G,t\mid t a t^{-1}=\phi(a) \forall a\in A\rangle$$ be an HNN extension, where \(\phi\from A\to B\) is an isomorphism between subgroups of \(G\). Any element \(h\in H\) can be written as a product $$h=g_0 t^{\epsilon_1}g_1t^{\epsilon_2} \dots g_{n-1}t^{\epsilon_{n}}g_n,$$ where \(g_i\in G\) and \(\epsilon_i\in \{-1,1\}\). Show that if \(h=1\) and \(n>0\), then the product contains a substring of the form \(tat^{-1}\) or \(t^{-1}bt\) for some \(a\in A\) or \(b\in B\).

Created: 2018-02-21 Wed 18:06

Emacs 24.5.1 (Org mode 8.2.10)

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