Brauer's Theorem On Forms

:''There also is Brauer's theorem on induced characters.''

In mathematics, Brauer's theorem, named for Richard Brauer, is a result on the representability of 0 by forms over certain fields in sufficiently many variables.

Statement of Brauer's theorem

Let ''K'' be a field such that for every integer ''r'' > 0 there exists an integer ψ(''r'') such that for ''n'' ≥ ψ(r) every equation

:$(*)\qquad a_1x_1^r+\cdots+a_nx_n^r=0,\quad a_i\in K,\quad i=1,\ldots,n$

has a non-trivial (i.e. not all ''x''_''i'' are equal to 0) solution in ''K''.
Then, given homogeneous polynomials ''f''₁,...,''f''_''k'' of degrees ''r''₁,...,''r''_''k'' respectively with coefficients in ''K'', for every set of positive integers ''r''₁,...,''r''_''k'' and every non-negative integer ''l'', there exists a number ω(''r''₁,...,''r''_''k'',''l'') such that for ''n'' ≥ ω(''r''₁,...,''r''_''k'',''l'') there exists an ''l''-dimensional affine subspace ''M'' of ''Kⁿ'' (regarded as a vector space over ''K'') satisfying

:$f_1(x_1,\ldots,x_n)=\cdots=f_k(x_1,\ldots,x_n)=0,\quad\forall(x_1,\ldots,x_n)\in M.$

An application to the field of p-adic numbers

Letting ''K'' be the field of p-adic numbers in the theorem, the equation (*) is satisfied, since $\mathbb_p^*/\left(\mathbb_p^*\right)^b$, ''b'' a natural number, is finite. Choosing ''k'' = 1, one obtains the following corollary:

:A homogeneous equation ''f''(''x''₁,...,''x''_''n'') = 0 of degree ''r'' in the field of p-adic numbers has a non-trivial solution if ''n'' is sufficiently large.

One can show that if ''n'' is sufficiently large according to the above corollary, then ''n'' is greater than ''r''². Indeed, Emil Artin conjectured that every homogeneous polynomial of degree ''r'' over Q_''p'' in more than ''r''² variables represents 0. This is obviously true for ''r'' = 1, and it is well known that the conjecture is true for ''r'' = 2 (see, for example, J.-P. Serre, ''A Course in Arithmetic'', Chapter IV, Theorem 6). See quasi-algebraic closure for further context.

In 1950 Demyanov verified the conjecture for ''r'' = 3 and ''p'' ≠ 3, and in 1952 D. J. Lewis independently proved the case ''r'' = 3 for all primes ''p''. But in 1966 Guy Terjanian constructed a homogeneous polynomial of degree 4 over Q₂ in 18 variables that has no non-trivial zero.Guy Terjanian, ''Un contre-exemple à une conjecture d'Artin'', C. R. Acad. Sci. Paris Sér. A–B, 262, A612, (1966) On the other hand, the Ax–Kochen theorem shows that for any fixed degree Artin's conjecture is true for all but finitely many Q_''p''.

Notes

*

References

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Diophantine equations
Theorems in number theory