Wedderburn's little theorem
In mathematics, Wedderburn's little theorem states that every finite division ring is a field. In other words, for finite rings, there is no distinction between domains, division rings and fields.
The Artin–Zorn theorem generalizes the theorem to alternative rings: every finite alternative division ring is a field.[1]
History
[edit]The original proof was given by Joseph Wedderburn in 1905,[2] who went on to prove the theorem in two other ways. Another proof was given by Leonard Eugene Dickson shortly after Wedderburn's original proof, and Dickson acknowledged Wedderburn's priority. However, as noted in (Parshall 1983), Wedderburn's first proof was incorrect – it had a gap – and his subsequent proofs appeared only after he had read Dickson's correct proof. On this basis, Parshall argues that Dickson should be credited with the first correct proof.
A simplified version of the proof was later given by Ernst Witt.[2] Witt's proof is sketched below. Alternatively, the theorem is a consequence of the Skolem–Noether theorem by the following argument.[3] Let be a finite division algebra with center . Let and denote the cardinality of . Every maximal subfield of has elements; so they are isomorphic and thus are conjugate by Skolem–Noether. But a finite group (the multiplicative group of in our case) cannot be a union of conjugates of a proper subgroup; hence, .
A later "group-theoretic" proof was given by Ted Kaczynski in 1964.[4] This proof, Kaczynski's first published piece of mathematical writing, was a short, two-page note which also acknowledged the earlier historical proofs.
Relationship to the Brauer group of a finite field
[edit]The theorem is essentially equivalent to saying that the Brauer group of a finite field is trivial. In fact, this characterization immediately yields a proof of the theorem as follows: let K be a finite field. Since the Herbrand quotient vanishes by finiteness, coincides with , which in turn vanishes by Hilbert 90.
The triviality of the Brauer group can also be obtained by direct computation, as follows. Let and let be a finite extension of degree so that Then is a cyclic group of order and the standard method of computing cohomology of finite cyclic groups shows that where the norm map is given by Taking to be a generator of the cyclic group we find that has order and therefore it must be a generator of . This implies that is surjective, and therefore is trivial.
Proof
[edit]Let A be a finite domain. For each nonzero x in A, the two maps
are injective by the cancellation property, and thus, surjective by counting. It follows from elementary group theory[5] that the nonzero elements of form a group under multiplication. Thus, is a skew-field.
To prove that every finite skew-field is a field, we use strong induction on the size of the skew-field. Thus, let be a skew-field, and assume that all skew-fields that are proper subsets of are fields. Since the center of is a field, is a vector space over with finite dimension . Our objective is then to show . If is the order of , then has order . Note that because contains the distinct elements and , . For each in that is not in the center, the centralizer of is clearly a skew-field and thus a field, by the induction hypothesis, and because can be viewed as a vector space over and can be viewed as a vector space over , we have that has order where divides and is less than . Viewing , , and as groups under multiplication, we can write the class equation
where the sum is taken over the conjugacy classes not contained within , and the are defined so that for each conjugacy class, the order of for any in the class is . and both admit polynomial factorization in terms of cyclotomic polynomials
The cyclotomic polynomials on are in and respect the following identities:
- and .
Because each is a proper divisor of ,
- divides both and each in ,
so by the above class equation, must divide , and therefore by taking the norms
- .
To see that this forces to be , we will show
for using factorization over the complex numbers. In the polynomial identity
where runs over the primitive -th roots of unity, set to be and then take absolute values
For , we see that for each primitive -th root of unity ,
because of the location of , , and in the complex plane. Thus
Notes
[edit]- ^ Shult, Ernest E. (2011). Points and lines. Characterizing the classical geometries. Universitext. Berlin: Springer-Verlag. p. 123. ISBN 978-3-642-15626-7. Zbl 1213.51001.
- ^ a b Lam (2001), p. 204
- ^ Theorem 4.1 in Ch. IV of Milne, class field theory, http://www.jmilne.org/math/CourseNotes/cft.html
- ^ Kaczynski, T.J. (June–July 1964). "Another Proof of Wedderburn's Theorem". American Mathematical Monthly. 71 (6): 652–653. doi:10.2307/2312328. JSTOR 2312328. (Jstor link, requires login)
- ^ e.g., Exercise 1-9 in Milne, group theory, http://www.jmilne.org/math/CourseNotes/GT.pdf
References
[edit]- Parshall, K. H. (1983). "In pursuit of the finite division algebra theorem and beyond: Joseph H M Wedderburn, Leonard Dickson, and Oswald Veblen". Archives of International History of Science. 33: 274–99.
- Lam, Tsit-Yuen (2001). A first course in noncommutative rings. Graduate Texts in Mathematics. Vol. 131 (2 ed.). Springer. ISBN 0-387-95183-0.