Let $M$ be a symmetric positive definite matrix, and let $a > 0$ be a given constant. Let $\text{vec}(\cdot)$ denote the operator that stacks vertically the columns of a $d \times d$ matrix into a $d^2 \times 1$ vector. Does there exists a matrix $S$ such that
$$ \text{vec}(M) \text{vec}(M)^{\top} + a \, (M \otimes M) = S \otimes S $$ ?
@Nathaniel Johnston already answered in comments. On a more general note, detecting whether a matrix is a sum of $r$ Kronecker products is essentially the same problem (up to a permutation of the entries) as determining whether a matrix has rank $r$.
Indeed, given a matrix $M\in\mathbb{F}^{am \times bn}$ (divided into blocks $M_{ij}$ each of size $m\times n$), rearrange its entries to form a matrix $N\in\mathbb{F}^{mn \times ab}$ such that each column of $N$ is the vectorization of a block $M_{ij}$; then a rank-$r$ decomposition of $N = u_1 v_1^T + \dots + u_r v_r^T$ corresponds to a decomposition of $M$ as sum of $r$ Kronecker products $M = \operatorname{vec}^{-1}(v_1) \otimes \operatorname{vec}^{-1}(u_1) + \dots + M = \operatorname{vec}^{-1}(v_r) \otimes \operatorname{vec}^{-1}(u_r)$.
