Reversible primes

Abstract: For an $n$-bit positive integer $a$ written in binary as $$ a = \sum_{j=0}^{n-1} \varepsilon_{j}(a) \,2^j $$ where, $\varepsilon_j(a) \in {0,1}$, $j\in{0, \ldots, n-1}$, $\varepsilon_{n-1}(a)=1$, let us define $$ \overleftarrow{a} = \sum_{j=0}^{n-1} \varepsilon_j(a)\,2^{n-1-j}, $$ the digital reversal of $a$. Also let $\mathcal{B}n = {2^{n-1}\leq a<2^n:~a \text{ odd}}.$ With a sieve argument, we obtain an upper bound of the expected order of magnitude for the number of $p \in \mathcal{B}_n$ such that $p$ and $\overleftarrow{p}$ are prime. We also prove that for sufficiently large $n$, $$ \left|{a \in \mathcal{B}_n:~ \max {\Omega (a), \Omega (\overleftarrow{a})}\le 8 }\right| \ge c\, \frac{2^n}{n^2}, $$ where $\Omega(n)$ denotes the number of prime factors counted with multiplicity of $n$ and $c > 0$ is an absolute constant. Finally, we provide an asymptotic formula for the number of $n$-bit integers $a$ such that $a$ and $\overleftarrow{a}$ are both squarefree. Our method leads us to provide various estimates for the exponential sum $$ \sum{a \in \mathcal{B}_n} \exp\left(2\pi i (\alpha a + \vartheta \overleftarrow{a})\right) \quad(\alpha,\vartheta \in\mathbb{R}). $$