It is well-known that the primes are uniformly distributed in residue classes modulo any fixed integer. More precisely, for each integer $q$ and each residue $a \in \mathbb{Z}/q\mathbb{Z}$ that is coprime to $q$, we have $$ \#\{ n < N : p_n \equiv a \bmod{q} \} \sim N/\varphi(q),$$ where, $p_n$ denotes the $n$-th prime and $\varphi(q)$ denotes the totient function. More precise bounds are also known, such as the Siegel–Walfisz theorem.
Is the analogous statement known for pairs of consecutive primes? Specifically, is it known that $$ \#\{ n < N : p_{n} \equiv a \bmod{q},\ p_{n+1} \equiv b \bmod{q}\} \sim N/\varphi(q)^2,$$ where $a,b$ are an arbitrary pair of residues coprime to $q$? I expect that the answer should be "no", since problems involving pairs of consecutive primes tend to be difficult.
