Interior products, exterior derivatives and one forms

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spaghetti3451
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If ##\bf{v}## is a vector and ##\alpha## is a ##p##-form, their interior product ##(p-1)##-form ##i_{\bf{v}}\alpha## is defined by##i_{\bf{v}}\alpha^{0}=\bf{0}####i_{\bf{v}}\alpha^{1}=\alpha({\bf{v}})####i_{\bf{v}}\alpha^{p}({\bf{w}}_{2},\dots,{\bf{w}}_{p})=\alpha^{p}({\bf{v}},{\bf{w}}_{2},\dots,{\bf{w}}_{p})##Now consider the following expressions, where ##\bf{d}## is the exterior derivative and ##\nu## is a ##1##=form.How do you prove that the two expressions are equal to each other?##i_{\bf{v}}\textbf{d}(\textbf{d}\nu)+\textbf{d}i_{\bf{v}}(\textbf{d}\nu)##

##\textbf{d}(i_{\bf{v}}\textbf{d}\nu)+\textbf{d}(\textbf{d}i_{\bf{v}}\nu)##
 
The exterior differentiation is nilpotent to a degree of 2. It won't commute with the interior differentiation*, therefore you need to consider the right order of operators, that is acting to the right (pun intended!).

*See below
 
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dextercioby, what do you mean by "interior differentiation" ?