Mason–Stothers theorem

The Mason–Stothers theorem, or simply Mason's theorem, is a mathematical theorem about polynomials, analogous to the abc conjecture for integers. It is named after W. Wilson Stothers, who published it in 1981,[1] and R. C. Mason, who rediscovered it shortly thereafter.[2]

The theorem states:

Let a(t), b(t), and c(t) be relatively prime polynomials over a field such that a + b = c and such that not all of them have vanishing derivative. Then

Here rad(f) is the product of the distinct irreducible factors of f. For algebraically closed fields it is the polynomial of minimum degree that has the same roots as f; in this case deg(rad(f)) gives the number of distinct roots of f.[3]

Examples

Proof

Snyder (2000) gave the following elementary proof of the Mason–Stothers theorem.[4]

Step 1. The condition a + b + c = 0 implies that the Wronskians W(a,b) = ab′ − ab, W(b,c), and W(c,a) are all equal. Write W for their common value.

Step 2. The condition that at least one of the derivatives a, b, or c is nonzero and that a, b, and c are coprime is used to show that W is nonzero. For example, if W = 0 then ab′ = ab so a divides a (as a and b are coprime) so a′ = 0 (as deg a > deg a unless a is constant).

Step 3. W is divisible by each of the greatest common divisors (a, a′), (b, b′), and (c, c′). Since these are coprime it is divisible by their product, and since W is nonzero we get

deg (a, a′) + deg (b, b′) + deg (c, c′) ≤ deg W.

Step 4. Substituting in the inequalities

deg (a, a′) ≥ deg a − (number of distinct roots of a)
deg (b, b′) ≥ deg b − (number of distinct roots of b)
deg (c, c′) ≥ deg c − (number of distinct roots of c)

(where the roots are taken in some algebraic closure) and

deg W ≤ deg a + deg b − 1

we find that

deg c ≤ (number of distinct roots of abc) − 1

which is what we needed to prove.

References

  1. Stothers, W. W. (1981), "Polynomial identities and hauptmoduln", Quarterly J. Math. Oxford, 2, 32: 349–370, doi:10.1093/qmath/32.3.349.
  2. Mason, R. C. (1984), Diophantine Equations over Function Fields, London Mathematical Society Lecture Note Series, 96, Cambridge, England: Cambridge University Press.
  3. Lang, Serge (2002). Algebra. New York, Berlin, Heidelberg: Springer-Verlag. p. 194. ISBN 0-387-95385-X.
  4. Snyder, Noah (2000), "An alternate proof of Mason's theorem" (PDF), Elemente der Mathematik, 55 (3): 93–94, doi:10.1007/s000170050074, MR 1781918.

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