Consider $\mathbb Q_p^{\text{ur}}$ the maximal unramified extension of the p-adic numbers. Suppose that on $\mathbb Q_p$ we have the usual absolute value that extends $|\frac{a}{b}|_p=\frac{1}{p^{v_p(a)-v_p(b)}}$ to $\mathbb Q_p$. Now it is known that $|\cdot|_p$ extends uniquely to $\mathbb Q_p^{\text{ur}}$. Is this absolute value discrete w.r.t. $\mathbb Q_p^{\text{ur}}$ ?
The relevant definitions can be found here (pages 105-124).
Since the extension of $|\cdot|_p$ is not discrete w.r.t. $\mathbb Q_p^{\text{al}}$, I had a first naive guess that this is also the case for $\mathbb Q_p^{\text{ur}}$. However, it is known that $\mathbb Q_p^{\text{ur}}$ is obtained by adjoining to $\mathbb Q_p^{\text{ur}}$ the roots of $1$ of order coprime to $p$, and obviously on each of these generators the absolute value must be $1$, which makes me believe the opposite, but how would one compute the absolute value for an arbitrary element in $\mathbb Q_p^{\text{ur}}$?
