Thom spaces (Ex)
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(Difference between revisions)
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\pi_{n+k}(\mathrm{Th}(\gamma_k))\to\pi_{n+k+1}(\mathrm{Th}(\gamma_{k+1})), | \pi_{n+k}(\mathrm{Th}(\gamma_k))\to\pi_{n+k+1}(\mathrm{Th}(\gamma_{k+1})), | ||
$$ | $$ | ||
− | where $\Sigma$ is the suspension homomorphism. Show that for all $k\geq0$ we have $P_n(\gamma_{k+1})\circ\Omega_n(\overline{i_k})=s_k\circ P_n(\gamma_k)$. | + | where $\Sigma$: $\pi_{n+k}(\mathrm{Th}(\gamma_k))\to\pi_{n+k+1}(\Sigma\mathrm{Th}(\gamma_k))$ is the suspension homomorphism. |
+ | Show that for all $k\geq0$ we have $P_n(\gamma_{k+1})\circ\Omega_n(\overline{i_k})=s_k\circ P_n(\gamma_k)$. | ||
{{endthm}} | {{endthm}} | ||
{{beginthm|Question}} | {{beginthm|Question}} |
Latest revision as of 09:47, 2 April 2012
Exercise 0.1. Let be -complexes and let be vector bundles over respectively. Denote by the product bundle over . Find homeomorphisms
With the following exercises we work out the details of [Lück2001, page 58f].
Exercise 0.2. Let be the universal oriented vector bundle of rank and let : be a bundle map. Define
Show that for all we have .
Exercise 0.3. Define
and
where : is the suspension homomorphism. Show that for all we have .
Question 0.4. Can we do similar things for unoriented manifolds, manifolds with spin structure,...?