Unimodular lattice
In geometry and mathematical group theory, a unimodular lattice is an integral lattice of determinant 1 or −1. For a lattice in n-dimensional Euclidean space, this is equivalent to requiring that the volume of any fundamental domain for the lattice be 1.
The E8 lattice and the Leech lattice are two famous examples.
Definitions
- A lattice is a free abelian group of finite rank with a symmetric bilinear form (·,·).
- The lattice is integral if (·,·) takes integer values.
- The dimension of a lattice is the same as its rank (as a Z-module).
- The norm of a lattice element a is (a, a).
- A lattice is positive definite if the norm of all nonzero elements is positive.
- The determinant of a lattice is the determinant of the Gram matrix, a matrix with entries (ai, aj), where the elements ai form a basis for the lattice.
- An integral lattice is unimodular if its determinant is 1 or −1.
- A unimodular lattice is even or type II if all norms are even, otherwise odd or type I.
- The minimum of a positive definite lattice is the lowest nonzero norm.
- Lattices are often embedded in a real vector space with a symmetric bilinear form. The lattice is positive definite, Lorentzian, and so on if its vector space is.
- The signature of a lattice is the signature of the form on the vector space.
Examples
The three most important examples of unimodular lattices are:
- The lattice Z, in one dimension.
- The E8 lattice, an even 8-dimensional lattice,
- The Leech lattice, the 24-dimensional even unimodular lattice with no roots.
Properties
A lattice is unimodular if and only if its dual lattice is integral. Unimodular lattices are equal to their dual lattices, and for this reason, unimodular lattices are also known as self-dual.
Given a pair (m,n) of nonnegative integers, an even unimodular lattice of signature (m,n) exists if and only if m-n is divisible by 8, but an odd unimodular lattice of signature (m,n) always exists. In particular, even unimodular definite lattices only exist in dimension divisible by 8. Examples in all admissible signatures are given by the IIm,n and Im,n constructions, respectively.
The theta function of a unimodular positive definite lattice is a modular form whose weight is one half the rank. If the lattice is even, the form has level 1, and if the lattice is odd the form has Γ0(4) structure (i.e., it is a modular form of level 4). Due to the dimension bound on spaces of modular forms, the minimum norm of a nonzero vector of an even unimodular lattice is no greater than ⎣n/24⎦ + 1. An even unimodular lattice that achieves this bound is called extremal. Extremal even unimodular lattices are known in relevant dimensions up to 80,[1] and their non-existence has been proven for dimensions above 163,264.[2]
Classification
For indefinite lattices, the classification is easy to describe. Write Rm,n for the m + n dimensional vector space Rm+n with the inner product of (a1, ..., am+n) and (b1, ..., bm+n) given by
In Rm,n there is one odd indefinite unimodular lattice up to isomorphism, denoted by
- Im,n,
which is given by all vectors (a1,...,am+n) in Rm,n with all the ai integers.
There are no indefinite even unimodular lattices unless
- m − n is divisible by 8,
in which case there is a unique example up to isomorphism, denoted by
- IIm,n.
This is given by all vectors (a1,...,am+n) in Rm,n such that either all the ai are integers or they are all integers plus 1/2, and their sum is even. The lattice II8,0 is the same as the E8 lattice.
Positive definite unimodular lattices have been classified up to dimension 25. There is a unique example In,0 in each dimension n less than 8, and two examples (I8,0 and II8,0) in dimension 8. The number of lattices increases moderately up to dimension 25 (where there are 665 of them), but beyond dimension 25 the Smith-Minkowski-Siegel mass formula implies that the number increases very rapidly with the dimension; for example, there are more than 80,000,000,000,000,000 in dimension 32.
In some sense unimodular lattices up to dimension 9 are controlled by E8, and up to dimension 25 they are controlled by the Leech lattice, and this accounts for their unusually good behavior in these dimensions. For example, the Dynkin diagram of the norm-2 vectors of unimodular lattices in dimension up to 25 can be naturally identified with a configuration of vectors in the Leech lattice. The wild increase in numbers beyond 25 dimensions might be attributed to the fact that these lattices are no longer controlled by the Leech lattice.
Even positive definite unimodular lattice exist only in dimensions divisible by 8. There is one in dimension 8 (the E8 lattice), two in dimension 16 (E82 and II16,0), and 24 in dimension 24, called the Niemeier lattices (examples: the Leech lattice, II24,0, II16,0 + II8,0, II8,03). Beyond 24 dimensions the number increases very rapidly; in 32 dimensions there are more than a billion of them.
Unimodular lattices with no roots (vectors of norm 1 or 2) have been classified up to dimension 28. There are none of dimension less than 23 (other than the zero lattice!). There is one in dimension 23 (called the short Leech lattice), two in dimension 24 (the Leech lattice and the odd Leech lattice), and Bacher & Venkov (2001) showed that there are 0, 1, 3, 38 in dimensions 25, 26, 27, 28, respectively. Beyond this the number increases very rapidly; there are at least 8000 in dimension 29. In sufficiently high dimensions most unimodular lattices have no roots.
The only non-zero example of even positive definite unimodular lattices with no roots in dimension less than 32 is the Leech lattice in dimension 24. In dimension 32 there are more than ten million examples, and above dimension 32 the number increases very rapidly.
The following table from (King 2003) gives the numbers of (or lower bounds for) even or odd unimodular lattices in various dimensions, and shows the very rapid growth starting shortly after dimension 24.
Dimension | Odd lattices | Odd lattices no roots |
Even lattices | Even lattices no roots |
---|---|---|---|---|
0 | 0 | 0 | 1 | 1 |
1 | 1 | 0 | ||
2 | 1 | 0 | ||
3 | 1 | 0 | ||
4 | 1 | 0 | ||
5 | 1 | 0 | ||
6 | 1 | 0 | ||
7 | 1 | 0 | ||
8 | 1 | 0 | 1 (E8 lattice) | 0 |
9 | 2 | 0 | ||
10 | 2 | 0 | ||
11 | 2 | 0 | ||
12 | 3 | 0 | ||
13 | 3 | 0 | ||
14 | 4 | 0 | ||
15 | 5 | 0 | ||
16 | 6 | 0 | 2 (E82, D16+) | 0 |
17 | 9 | 0 | ||
18 | 13 | 0 | ||
19 | 16 | 0 | ||
20 | 28 | 0 | ||
21 | 40 | 0 | ||
22 | 68 | 0 | ||
23 | 117 | 1 (shorter Leech lattice) | ||
24 | 273 | 1 (odd Leech lattice) | 24 (Niemeier lattices) | 1 (Leech lattice) |
25 | 665 | 0 | ||
26 | ≥ 2307 | 1 | ||
27 | ≥ 14179 | 3 | ||
28 | ≥ 327972 | 38 | ||
29 | ≥ 37938009 | ≥ 8900 | ||
30 | ≥ 20169641025 | ≥ 82000000 | ||
31 | ≥ 5000000000000 | ≥ 800000000000 | ||
32 | ≥ 80000000000000000 | ≥ 10000000000000000 | ≥ 1160000000 | ≥ 10900000 |
Beyond 32 dimensions, the numbers increase even more rapidly.
Applications
The second cohomology group of a closed simply connected oriented topological 4-manifold is a unimodular lattice. Michael Freedman showed that this lattice almost determines the manifold: there is a unique such manifold for each even unimodular lattice, and exactly two for each odd unimodular lattice. In particular if we take the lattice to be 0, this implies the Poincaré conjecture for 4-dimensional topological manifolds. Donaldson's theorem states that if the manifold is smooth and the lattice is positive definite, then it must be a sum of copies of Z, so most of these manifolds have no smooth structure. One such example is the E8 manifold.
References
- Nebe, Gabriele; Sloane, Neil. "Unimodular Lattices, Together With A Table of the Best Such Lattices". Online Catalogue of Lattices. Retrieved 2015-05-30.
- Nebe, Gabriele (2013). "Boris Venkov's Theory of Lattices and Spherical Designs". In Wan, Wai Kiu; Fukshansky, Lenny; Schulze-Pillot, Rainer; et al. (eds.). Diophantine methods, lattices, and arithmetic theory of quadratic forms. Contemporary Mathematics. 587. Providence, RI: American Mathematical Society. pp. 1–19. arXiv:1201.1834. Bibcode:2012arXiv1201.1834N. MR 3074799.
- Bacher, Roland; Venkov, Boris (2001), "Réseaux entiers unimodulaires sans racine en dimension 27 et 28" [Unimodular integral lattices without roots in dimensions 27 and 28], in Martinet, Jacques (ed.), Réseaux euclidiens, designs sphériques et formes modulaires [Euclidean lattices, spherical designs and modular forms], Monogr. Enseign. Math. (in French), 37, Geneva: L'Enseignement Mathématique, pp. 212–267, ISBN 2-940264-02-3, MR 1878751, Zbl 1139.11319, archived from the original on 2007-09-28
- Conway, J.H.; Sloane, N.J.A. (1999), Sphere packings, lattices and groups, Grundlehren der Mathematischen Wissenschaften, 290, With contributions by Bannai, E.; Borcherds, R.E.; Leech, J.; Norton, S.P.; Odlyzko, A.M.; Parker, R.A.; Queen, L.; Venkov, B.B. (Third ed.), New York, NY: Springer-Verlag, ISBN 0-387-98585-9, MR 0662447, Zbl 0915.52003
- King, Oliver D. (2003), "A mass formula for unimodular lattices with no roots", Mathematics of Computation, 72 (242): 839–863, arXiv:math.NT/0012231, Bibcode:2003MaCom..72..839K, doi:10.1090/S0025-5718-02-01455-2, MR 1954971, Zbl 1099.11035
- Milnor, John; Husemoller, Dale (1973), Symmetric Bilinear Forms, Ergebnisse der Mathematik und ihrer Grenzgebiete, 73, New York-Heidelberg: Springer-Verlag, doi:10.1007/978-3-642-88330-9, ISBN 3-540-06009-X, MR 0506372, Zbl 0292.10016
- Serre, Jean-Pierre (1973), A Course in Arithmetic, Graduate Texts in Mathematics, 7, Springer-Verlag, doi:10.1007/978-1-4684-9884-4, ISBN 0-387-90040-3, MR 0344216, Zbl 0256.12001
- Freedman, Michael H. (1982), "The topology of four-dimensional manifolds", J. Differential Geom., 17 (3): 357–453, doi:10.4310/jdg/1214437136
External links
- Neil Sloane's catalogue of unimodular lattices.
- OEIS sequence A005134 (Number of n-dimensional unimodular lattices)