Coefficient-Level Böttcher Theory for Wild Superattracting Germs of Degree pe

Abstract

Let p be an odd prime, let e2, and put q=pe. We study the wild family \[ φr,e(x)=xq+qpr xq+1=xpe+pr+expe+1 (r0), \] and the inverse Böttcher coordinate fr,e(x)=xΣk0ak(r,e)xk/k! characterized by \[ φr,e(fr,e(x))=fr,e(xq). \] For the clean family, we prove a complete mod-p digit-sum law in the special fiber r=0. For the higher fibers r1, we prove a coefficient-level theorem consisting of a global digit-weight lower bound, a leading monomial theorem on divisible non-pure classes, a lag-e pure-power recursion, and subadditivity of the induced digit weight. This yields the pure-power branch word \[ (Be-1A) r/eB∞ \] and the radius formula \[ ρ(fr,e)=p-θr,e, θr,e=p-e r/e(1p-1+e r/e-r). \] We then prove a tail-stable extension. In the special fiber, p-divisible tails preserve the digit-sum law modulo p. In the higher fibers, tails satisfying vp(h)Λr,e(h+1)+1 lie beyond the clean-family initial Λr,e-graded term and therefore preserve the leading terms, the pure-power branch word, the valuation asymptotic, and the radius. For e=2, this recovers the Salerno--Silverman degree-p2 family and the Fu--Nie radius statement for the inverse coordinate in that family.