Let's use some standard bounds on the $n$th prime, as found in [this paper][1] by Pierre Dusart.

We have
$$
p_{2n} \leq 2n[\ln(2n)+\ln(\ln(2n))-0.9484] = 2n\left[\ln(n)+\ln\left(\frac{2}{e^{0.9484}}\ln(2n)\right)\right]
$$
using an inequality stated on page 414 of the cited paper, valid for $n\geq 19509$.  On the other hand, we have
$$2n\ln(p_n)\geq 2n\ln[n(\ln(n)+\ln(\ln(n))-1)]=2n[\ln(n)+\ln(\ln(n\ln(n)/e))]
$$
by the main result of that paper, for $n\geq 2$.

Thus, your desired inequality will be true once $n\geq 19509$ and when
$$\frac{2}{e^{0.9484}}\ln(2n)<\ln\left(\frac{n\ln(n)}{e}\right).
$$
That last inequality becomes true when $n\geq 13$.  Then a simple check will show that the inequality you want is valid in the region $52\leq n\leq 19509$.


  [1]: https://www.ams.org/journals/mcom/1999-68-225/S0025-5718-99-01037-6/S0025-5718-99-01037-6.pdf