On rank in algebraic closure

Abstract: Let $ {\mathbf k} $ be a field and $Q\in {\mathbf k}[x_1, \ldots, x_s]$ a form (homogeneous polynomial) of degree $d>1.$ The ${\mathbf k}$-Schmidt rank $rk_{\mathbf k}(Q)$ of $Q$ is the minimal $r$ such that $Q= \sum_{i=1}^r R_iS_i$ with $R_i, S_i \in {\mathbf k}[x_1, \ldots, x_s]$ forms of degree $<d$. When $ {\mathbf k} $ is algebraically closed, this rank is essentially equivalent to the codimension in $ {\mathbf k}^s $ of the singular locus of the variety defined by $ Q, $ known also as the Birch rank of $ Q. $ When $ {\mathbf k} $ is a number field, a finite field or a function field, we give polynomial bounds for $ rk_{\mathbf k}(Q) $ in terms of $ rk_{\bar {\mathbf k}} (Q) $ where $ \bar {\mathbf k} $ is the algebraic closure of $ {\mathbf k}. $ Prior to this work no such bound (even ineffective) was known for $d\>4$. This result has immediate consequences for counting integer points (when $ {\mathbf k} $ is a number field) or prime points (when $ {\mathbf k} = \mathbb Q $) of the variety $ {Q=0} $ assuming $ rk_{\mathbf k} (Q) $ is large.