I have some aside computations to make in order to understand a proof in some online Morse Theory notes.
Here, let $M$ be a $n$-dimensional manifold. $TM$ and $NM$ are respectively the tangent and normal bundles of $M$.
I really do not get how the author can say that the bundle
$\Gamma:=\bigwedge^n TM\otimes_{\mathbb{R}}\bigwedge^{k}NM,$
is a trivial one. I tried to use the following identities : if $V$ and $W$ are two vector spaces over $\mathbb{R}$ then
$\wedge(V\oplus_{\mathbb{R}} W)\cong \wedge V\oplus_{\mathbb{R}}\wedge W,$
and
$\bigoplus_{k=0}^n\{\bigwedge^k V\otimes_{\mathbb{R}}\bigwedge^{n-k}W\}\cong \bigwedge^n(V\oplus_{\mathbb{R}}W).$
I do not want to pass too much time on this computation since it's just a tiny part of the proof, but I would really appreciate any help!
Thanks in advance! :-)
Well, then you have it with the information you already knew and the information you provided. $TX|_M \cong TM\oplus NM$, and $\Lambda^{n+k}(TX|_M) \cong \Lambda^n M\otimes\Lambda^k NM$. But $\Lambda^{n+k}(TX)$ is a trivial line bundle, since $X$ is orientable, so, in particular, its restriction to $M$ is likewise trivial.