Can there exist a right invariant killing field of a right invariant (but not bi-invariant) Riemannian metric on a Lie group?
I am especially interested in the case of $SU(N)$ with a metric of the form (at the identity): $g(x,y) = \frac{1}{\lambda} B(x,y) + \frac{1}{\lambda^2} B(x,w)B(y,w)$ where $w$ is an arbitrary given vector in $\mathfrak{su}(n)$ s.t. B(w,w) < 1 and B is the Killing form (taken to be positive definite).
A right invariant Riemannian metric is invariant und all right translations. A left invariant vector field has a flow consisting of right translations (by $\exp(tX)$). Thus each left invariant field is a Killing field. A right invariant field $R_X$ is Killing if and only if $S^2(\text{ad}_X)^*g_{e}=0$.
There is an obvious right-invariant vector field which leaves that metric invariant: the one which extends $w$. As Peter Michor mentions in his answer, the condition for a right-invariant vector field to be Killing is that it should preserve the inner product at the identity. In your example, and letting $b = \lambda^{-1} B$, and using the ad-invariance of the Killing form, $$ (\operatorname{ad}_z^* g)(x,y) = - b(x,[z,w])b(y,w) - b(x,w)b(y,[z,w]) $$ which vanishes for $z = w$.
