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On rank in algebraic closure

Amichai Lampert, Tamar Ziegler

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.

On rank in algebraic closure

Abstract

Let be a field and a form (homogeneous polynomial) of degree The -Schmidt rank of is the minimal such that with forms of degree . When is algebraically closed, this rank is essentially equivalent to the codimension in of the singular locus of the variety defined by known also as the Birch rank of When is a number field, a finite field or a function field, we give polynomial bounds for in terms of where is the algebraic closure of Prior to this work no such bound (even ineffective) was known for . This result has immediate consequences for counting integer points (when is a number field) or prime points (when ) of the variety assuming is large.
Paper Structure (11 sections, 18 theorems, 80 equations)

This paper contains 11 sections, 18 theorems, 80 equations.

Key Result

Theorem 1.3

Let ${\mathbf k}$ be an admissible field, $\bar{{\mathbf k}}$ its algebraic closure, and $Q\in {\mathbf k}[x_1, \ldots, x_s]$ a polynomial of degree $d>1$ such that $\textnormal{char}({\mathbf k}) > d$ or $\textnormal{char}({\mathbf k}) = 0.$ Then there exist constants $A = A({\mathbf k},d), B = B({

Theorems & Definitions (50)

  • Definition 1.1
  • Definition 1.2
  • Theorem 1.3: Schmidt rank and field extensions
  • Definition 1.4
  • Theorem 1.5: Schmidt rank and field extensions
  • Conjecture 1.6
  • Definition 2.1
  • Theorem 2.2: Theorem 1.4 in KP21
  • Corollary 2.3
  • proof
  • ...and 40 more