Haran's diamond theorem
In mathematics, the Haran diamond theorem gives a general sufficient condition for a separable extension of a Hilbertian field to be Hilbertian.
Statement of the diamond theorem
[edit]
Let K be a Hilbertian field and L a separable extension of K. Assume there exist two Galois extensions N and M of K such that L is contained in the compositum NM, but is contained in neither N nor M. Then L is Hilbertian.
The name of the theorem comes from the pictured diagram of fields, and was coined by Jarden.
Some corollaries
[edit]Weissauer's theorem
[edit]This theorem was firstly proved using non-standard methods by Weissauer. It was reproved by Fried using standard methods. The latter proof led Haran to his diamond theorem.
- Weissauer's theorem
Let K be a Hilbertian field, N a Galois extension of K, and L a finite proper extension of N. Then L is Hilbertian.
- Proof using the diamond theorem
If L is finite over K, it is Hilbertian; hence we assume that L/K is infinite. Let x be a primitive element for L/N, i.e., L = N(x).
Let M be the Galois closure of K(x). Then all the assumptions of the diamond theorem are satisfied, hence L is Hilbertian.
Haran–Jarden condition
[edit]Another, preceding to the diamond theorem, sufficient permanence condition was given by Haran–Jarden: Theorem. Let K be a Hilbertian field and N, M two Galois extensions of K. Assume that neither contains the other. Then their compositum NM is Hilbertian.
This theorem has a very nice consequence: Since the field of rational numbers, Q is Hilbertian (Hilbert's irreducibility theorem), we get that the algebraic closure of Q is not the compositum of two proper Galois extensions.
References
[edit]- Haran, Dan (1999), "Hilbertian fields under separable algebraic extensions", Inventiones Mathematicae, 137 (1): 113–126, Bibcode:1999InMat.137..113H, doi:10.1007/s002220050325, MR 1702139, S2CID 120002473, Zbl 0933.12003.
- Fried, Michael D.; Jarden, Moshe (2008), Field Arithmetic, Ergebnisse der Mathematik und ihrer Grenzgebiete. 3 Folge, vol. 11 (3rd revised ed.), Berlin: Springer-Verlag, ISBN 978-3-540-77269-9, MR 2445111, Zbl 1145.12001.