My question concerns the following:
For a given polynomial $F(x) = a_n x^n + \cdots + a_0$ with a root $F(x) = 0 , x \in \Omega_p$, (that is the completion of the p-adic numbers) and $a_j \in Z_p$, we can find the valuation of the root through Newton Polygons. We also know that an arbitrary non-zero element $x \in \Omega_p$ can be written as $p^r ab$, where '$a$' is a $(p^l -1)$th root of unity (i.e. a Teichmuller lift) and '$b$' is an element in the open unit disk about 1 (i.e. $b = 1 + M, |M|_p < 1$) (page 100 here).
The question is, for a given root of the polynomial with non-zero valuation, can we find out information concerning which kind of root of unity it is a product of, i.e. the order of '$a$' or terms of its algebraic expansion (such as discussed here), from information we have regarding the polynomial?
Thank you.
You didn’t say anything about the nature of the number $r$ in the expression $p^r$. In fact, $r$ may be any rational number. This requires giving an unambiguous definition of $p^r$ for any rational number $r$. This may be done, but only with an appeal to the Axiom of Choice, and amounts to a choice of a homomorphism $\xi:\Bbb Q^+\to\Omega^\times$ satisfying $\xi(1)=p$, where $\Omega$ is your complete algebraically closed field.
Once this is done, your task is easy. Take your $p$-adic quantity $x$, say $v_p(x)=m/n\in\Bbb Q$, not necessarily an integer since $x$ is not necessarily in $\Bbb Q_p$. Then $x/\xi(m/n)$ is a unit in the field $\Bbb Q_p(x,\xi(1/n))$, reducing modulo the maximal ideal to $\tilde a$ in some finite field $\Bbb F$. This lifts to a (unique) root of unity $a$, so we have $x/\xi(m/n)=ab$, where $b$ is a “principal unit”, i.e. congruent to $1$ modulo the maximal ideal. And there you are.
But notice that everything depends on your uniform choice of roots of $p$.
I think the utility of the decomposition $x=p^rab$ is in defining a logarithm on all of $\Omega^\times$; you define $\log(p)=1$, and use the analytic definition of $\log$ on $1+\mathfrak M$; the logarithm of any root of unity is necessarily $0$ to preserve the homomorphism property (and comes for free when the root of unity is in $1+\mathfrak M$). Then the ambiguity of our definition of $p^r$ no longer matters.