Question: Suppose that in a certain town earthquakes occur as a Poisson point process with an average of 3 per decade, floods are a Poisson process with an average of 2 per decade, and meteor strikes are a Poisson process with an average of 1 per decade. Consider the present to be time zero, and write $E$, $F$ and $M$ for the time in decades between the present and the first earthquake, flood, and meteor strike (respectively). Compute $\mbox{Cov}(\min\{E, F, M\}, M)$.
By reading the brief solution, I understand that the process starts by "adding nothing" to obtain
$\mbox{Cov}(\min\{E, F, M\}, M) = \mbox{Cov}(\min\{E, F, M\}, M - \min\{E, F, M\} + \min\{E, F, M\})$.
Then it splits this up using bilinearity into
$\mbox{Cov}(\min\{E, F, M\}, \min\{E, F, M\}) + \mbox{Cov}(\min\{E, F, M\}, M - \min\{E, F, M\})$
The left component is just $\mbox{Cov}(\min\{E, F, M\}, \min\{E, F, M\}) = \mbox{Var}(\min\{E, F, M\}) = 6^2$ (or $1/6^2$ depending on what definition you use). I understand that.
But it also says that, due to the memoryless property, the right hand component is zero becuse the two random variables are independent (that's a simple fact about covariances). But I'm not intuitively seeing the connection between the memoryless property and the fact that $\min\{E,F,M\}$ and $M - \min\{E,F,M\}$ are independent.
UPDATE: Just to make things clear, the solutions manual gives the final answer as $1/6^2$.