Let $G={\rm SL}(2,\Bbb C)$, and let $R$ denote the natural 2-dimensional representation of $G$ in ${\Bbb C}^2$.
For an integer $p\ge 0$, write $R_p=S^p R$; then $R_1=R$ and  ${\rm dim}\, R_p=p+1$.

Using Table 5 in the book of Onishchik and Vinberg, I computed that the representation
$$ R_2\otimes\Lambda^2 R_4 $$
contains the trivial representation with multiplicity one.
I used the table as a black box. 

>  **Question.** Let $V\subset  R_2\otimes\Lambda^2 R_4$ denote the corresponding one-dimensional subspace. 
How can one describe $V$ as a subspace ***geometrically***?

**Motivation:** I want to consider a ${\rm PGL}(2,k)$-fixed trivector 
$$v\in V\subset R_2\otimes\Lambda^2 R_4\subset \Lambda^3(R_2\oplus R_4)$$
of  the 8-dimensional vector space $W=R_2\oplus R_4$ over a field $k$, 
and then to twist all this using a Galois-cocycle of ${\rm PGL}(2,k)$. For this end I need a geometric description of $V$.

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