Chevalley–Warning theorem

In number theory, the Chevalley–Warning theorem implies that certain polynomial equations in sufficiently many variables over a finite field have solutions. It was proved by Ewald Warning (1935) and a slightly weaker form of the theorem, known as Chevalley's theorem, was proved by Chevalley (1935). Chevalley's theorem implied Artin's and Dickson's conjecture that finite fields are quasi-algebraically closed fields (Artin 1982).

Let ${\displaystyle \mathbb{𝔽}}$ be a finite field and ${\displaystyle \{f_j{\}}_{j=1}^r\subseteq \mathbb{𝔽}[X_1,\dots ,X_n]}$ be a set of polynomials such that the number of variables satisfies

${\displaystyle n>{\displaystyle \sum _{j=1}^r}{d}_j}$

where ${\displaystyle d_j}$ is the total degree of ${\displaystyle f_j}$. The theorems are statements about the solutions of the following system of polynomial equations

${\displaystyle f_j(x_1,\dots ,x_n)=0\text{for}j=1,\dots ,r.}$

• The Chevalley–Warning theorem states that the number of common solutions ${\displaystyle (a_1,\dots ,a_n)\in {\mathbb{𝔽}}^n}$ is divisible by the characteristic ${\displaystyle p}$ of ${\displaystyle \mathbb{𝔽}}$. Or in other words, the cardinality of the vanishing set of ${\displaystyle \{f_j{\}}_{j=1}^r}$ is ${\displaystyle 0}$ modulo ${\displaystyle p}$.
• The Chevalley theorem states that if the system has the trivial solution ${\displaystyle (0,\dots ,0)\in {\mathbb{𝔽}}^n}$, that is, if the polynomials have no constant terms, then the system also has a non-trivial solution ${\displaystyle (a_1,\dots ,a_n)\in {\mathbb{𝔽}}^n\mathrm{\setminus }\{(0,\dots ,0)\}}$.

Chevalley's theorem is an immediate consequence of the Chevalley–Warning theorem since ${\displaystyle p}$ is at least 2.

Both theorems are best possible in the sense that, given any ${\displaystyle n}$, the list ${\displaystyle f_j=x_j,j=1,\dots ,n}$ has total degree ${\displaystyle n}$ and only the trivial solution. Alternatively, using just one polynomial, we can take f₁ to be the degree n polynomial given by the norm of x₁a₁ + ... + x_na_n where the elements a form a basis of the finite field of order pⁿ.

Warning proved another theorem, known as Warning's second theorem, which states that if the system of polynomial equations has the trivial solution, then it has at least ${\displaystyle q^{n-d}}$ solutions where ${\displaystyle q}$ is the size of the finite field and ${\displaystyle d:=d_1+\dots +d_r}$. Chevalley's theorem also follows directly from this.

Remark: If ${\displaystyle i<q-1}$ then

${\displaystyle \sum _{x\in \mathbb{𝔽}}{x}^i=0}$

so the sum over ${\displaystyle {\mathbb{𝔽}}^n}$ of any polynomial in ${\displaystyle x_1,\dots ,x_n}$ of degree less than ${\displaystyle n(q-1)}$ also vanishes.

The total number of common solutions modulo ${\displaystyle p}$ of ${\displaystyle f_1,\dots ,f_r=0}$ is equal to

${\displaystyle \sum _{x\in {\mathbb{𝔽}}^n}(1-f_1^{q-1}(x))\cdot \dots \cdot (1-f_r^{q-1}(x))}$

because each term is 1 for a solution and 0 otherwise. If the sum of the degrees of the polynomials ${\displaystyle f_i}$ is less than n then this vanishes by the remark above.

It is a consequence of Chevalley's theorem that finite fields are quasi-algebraically closed. This had been conjectured by Emil Artin in 1935. The motivation behind Artin's conjecture was his observation that quasi-algebraically closed fields have trivial Brauer group, together with the fact that finite fields have trivial Brauer group by Wedderburn's theorem.

The Ax–Katz theorem, named after James Ax and Nicholas Katz, determines more accurately a power ${\displaystyle q^b}$ of the cardinality ${\displaystyle q}$ of ${\displaystyle \mathbb{𝔽}}$ dividing the number of solutions; here, if ${\displaystyle d}$ is the largest of the ${\displaystyle d_j}$, then the exponent ${\displaystyle b}$ can be taken as the ceiling function of

${\displaystyle \frac{n-\sum _j{d}_j}{d}.}$

The Ax–Katz result has an interpretation in étale cohomology as a divisibility result for the (reciprocals of) the zeroes and poles of the local zeta-function. Namely, the same power of ${\displaystyle q}$ divides each of these algebraic integers.

• Combinatorial Nullstellensatz

• Artin, Emil (1982), Lang, Serge.; Tate, John, eds., Collected papers, Berlin, New York: Springer-Verlag, ISBN 978-0-387-90686-7 
• Ax, James (1964), "Zeros of polynomials over finite fields", American Journal of Mathematics 86: 255–261, doi:10.2307/2373163 
• Chevalley, Claude (1935), "Démonstration d'une hypothèse de M. Artin" (in French), Abhandlungen aus dem Mathematischen Seminar der Universität Hamburg 11: 73–75, doi:10.1007/BF02940714 
• Katz, Nicholas M. (1971), "On a theorem of Ax", Amer. J. Math. 93 (2): 485–499, doi:10.2307/2373389 
• Warning, Ewald (1935), "Bemerkung zur vorstehenden Arbeit von Herrn Chevalley" (in German), Abhandlungen aus dem Mathematischen Seminar der Universität Hamburg 11: 76–83, doi:10.1007/BF02940715 
• Serre, Jean-Pierre (1973), A course in arithmetic, pp. 5–6, ISBN 0-387-90040-3, https://archive.org/details/courseinarithmet00serr/page/5 

• "Proofs of the Chevalley-Warning theorem". https://mathoverflow.net/q/178318. 

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