In mathematics, the Leech lattice is an even unimodular lattice ÃÂ<sub>24</sub> in 24-dimensional Euclidean space, E<sup>24</sup>. It is one of the best models for the kissing number problem. It was discovered by . It may also have been discovered (but not published) by Ernst Witt in 1940.
The Leech lattice ÃÂ<sub>24</sub> is the unique lattice in 24-dimensional Euclidean space, E<sup>24</sup>, with the following list of properties:
The last condition is equivalent to the condition that unit balls centered at the points of ÃÂ<sub>24</sub> do not overlap. Each is tangent to 196,560 neighbors, and this is known to be the largest number of non-overlapping 24-dimensional unit balls that can simultaneously touch a single unit ball. This arrangement of 196,560 unit balls centred about another unit ball is so efficient that there is no room to move any of the balls; this configuration and its mirror image are the only 24-dimensional arrangements where 196,560 unit balls simultaneously touch another. This property is also true in 1, 2, and 8 dimensions, with 2, 6, and 240 unit balls, respectively, based on the integer lattice, hexagonal tiling, and E<sub>8</sub> lattice, respectively.
It has no root system and in fact is the first unimodular lattice with no roots (vectors of norm less than 4), and therefore has a centre density of 1. By multiplying this value by the volume of a unit ball in 24 dimensions, , its absolute density can be derived.
showed that the Leech lattice is isometric to the set of simple roots (or the Dynkin diagram) of the reflection group of the 26-dimensional even Lorentzian unimodular lattice II<sub>25,1</sub>. By comparison, the Dynkin diagrams of II<sub>9,1</sub> and II<sub>17,1</sub> are finite.
The binary Golay code, independently developed in 1949, is an application in coding theory. More specifically, it is an error-correcting code capable of correcting up to three errors in each 24-bit word, and detecting up to four. It was used to communicate with the Voyager probes, as it is much more compact than the previously used Hadamard code.
Quantizers, or analog-to-digital converters, can use lattices to minimise the average root-mean-square error. Most quantizers are based on the one-dimensional integer lattice, but using multi-dimensional lattices reduces the RMS error. The Leech lattice is a good solution to this problem, as the Voronoi cells have a low second moment.
The vertex algebra of the two-dimensional conformal field theory describing bosonic string theory, compactified on the 24-dimensional quotient torus R<sup>24</sup>/ÃÂ<sub>24</sub> and orbifolded by a two-element reflection group, provides an explicit construction of the Griess algebra that has the monster group as its automorphism group. This monster vertex algebra was also used to prove the monstrous moonshine conjectures.
The Leech lattice can be constructed in a variety of ways. Like all lattices, it can be constructed by taking the integral span of the columns of its generator matrix, a 24×24 matrix with determinant 1.
The Leech lattice can be explicitly constructed as the set of vectors of the form 2<sup>−3/2</sup>(a<sub>1</sub>, a<sub>2</sub>, ..., a<sub>24</sub>), where the a<sub>i</sub> are integers such that
and for each fixed residue class modulo 4, the 24 bit word, whose 1s correspond to the coordinates i such that a<sub>i</sub> belongs to this residue class, is a word in the binary Golay code. The Golay code, together with the related Witt design, features in a construction for the 196560 minimal vectors in the Leech lattice.
The Leech lattice (L mod 8) can be directly constructed by combinations of the 3 following sets:
where is a ones vector of size n, is the 24-bit Golay code, is the sequence of 24-bit integers, and is the Thue-Morse sequence or integer bit parity sum (that give the chirality of the lattice).
The Leech lattice can also be constructed as , where is the Weyl vector
in the 26-dimensional even Lorentzian unimodular lattice II<sub>25,1</sub>. The existence of such an integral vector of Lorentzian norm zero relies on the fact that 1<sup>2</sup> + 2<sup>2</sup> + ... + 24<sup>2</sup> is a perfect square (in fact 70<sup>2</sup>); the number 24 is the only integer bigger than 1 with this property (see cannonball problem). This was conjectured by ÃÂdouard Lucas, but the proof came much later, based on elliptic functions.
The vector in this construction is really the Weyl vector of the even sublattice D<sub>24</sub> of the odd unimodular lattice I<sup>25</sup>. More generally, if L is any positive definite unimodular lattice of dimension 25 with at least 4 vectors of norm 1, then the Weyl vector of its norm 2 roots has integral length, and there is a similar construction of the Leech lattice using L and this Weyl vector.
described another 23 constructions for the Leech lattice, each based on a Niemeier lattice. It can also be constructed by using three copies of the E<sub>8</sub> lattice, in the same way that the binary Golay code can be constructed using three copies of the extended Hamming code, H<sub>8</sub>. This construction is known as the Turyn construction of the Leech lattice.
Starting with a single point, ÃÂ<sub>0</sub>, stack copies of the lattice ÃÂ<sub>n</sub> can be stacked to form an (n + 1)-dimensional lattice, ÃÂ<sub>n+1</sub>, without reducing the minimal distance between points. ÃÂ<sub>1</sub> corresponds to the integer lattice, ÃÂ<sub>2</sub> is to the hexagonal lattice, and ÃÂ<sub>3</sub> is the face-centered cubic packing. showed that the Leech lattice is the unique laminated lattice in 24 dimensions.
The Leech lattice is also a 12-dimensional lattice over the Eisenstein integers. This is known as the complex Leech lattice, and is isomorphic to the 24-dimensional real Leech lattice. In the complex construction of the Leech lattice, the binary Golay code is replaced with the ternary Golay code, and the Mathieu group M<sub>24</sub> is replaced with the Mathieu group M<sub>12</sub>. The E<sub>6</sub> lattice, E<sub>8</sub> lattice, and Coxeter–Todd lattice also have constructions as complex lattices, over either the Eisenstein or Gaussian integers.
The Leech lattice can also be constructed using the ring of icosians. The icosian ring is abstractly isomorphic to the E<sub>8</sub> lattice, three copies of which can be used to construct the Leech lattice using the Turyn construction.
In 1972 Witt gave the following construction, which he said he found in 1940, on January 28. Suppose that H is an n àn Hadamard matrix, where n = 4ab. Then the matrix defines a bilinear form in 2n dimensions, whose kernel has n dimensions. The quotient by this kernel is a nonsingular bilinear form taking values in (1/2)Z. It has 3 sublattices of index 2 that are integral bilinear forms. Witt obtained the Leech lattice as one of these three sublattices by taking a = 2, b = 3, and taking H to be the 24 à24 matrix (indexed by Z/23Z ⪠âÂÂ) with entries ç(m+n) where ç(âÂÂ)=1, ç(0)=âÂÂ1, and ç(n)=is the quadratic residue symbol mod 23 for nonzero n. This matrix H is a Paley matrix with some insignificant sign changes.
described a construction using a skew Hadamard matrix of Paley type. The Niemeier lattice with root system can be made into a module for the ring of integers of the field . Multiplying this Niemeier lattice by a non-principal ideal of the ring of integers gives the Leech lattice.
constructed the Leech lattice using higher power residue codes over the ring . A similar construction is used to construct some of the other lattices of rank 24.
If L is the set of octonions with coordinates on the lattice, then the Leech lattice is the set of triplets such that
where . This construction is due to .
The Leech lattice is highly symmetrical. Its automorphism group is the Conway group Co<sub>0</sub>, which is of order . The center of Co<sub>0</sub> has two elements, and the quotient of Co<sub>0</sub> by this center is the Conway group Co<sub>1</sub>, a finite simple group, and one of the sporadic groups. Many other sporadic groups, such as the remaining Conway groups and Mathieu groups, can be constructed as the stabilizers of various configurations of vectors in the Leech lattice.
Despite having such a high rotational symmetry group, the Leech lattice does not possess any hyperplanes of reflection symmetry. In other words, the Leech lattice is chiral. It also has far fewer symmetries than the 24-dimensional hypercube and simplex, or even the Cartesian product of three copies of the E<sub>8</sub> lattice.
The automorphism group was first described by John Conway. The vectors of norm 8 fall into "crosses" of 48 vectors. Each cross contains 24 mutually orthogonal vectors and their negatives, and thus describe the vertices of a 24-dimensional orthoplex. Each of these crosses can be taken to be the coordinate system of the lattice, and has the same symmetry of the Golay code, namely . Hence the full automorphism group of the Leech lattice has order × 4096 × , or .
showed that the covering radius of the Leech lattice is ; in other words, if a closed ball of this radius is placed around each lattice point, then these just cover Euclidean space. The points at distance at least from all lattice points are called the deep holes of the Leech lattice. There are 23 orbits of them under the automorphism group of the Leech lattice, and these orbits correspond to the 23 Niemeier lattices other than the Leech lattice: the set of vertices of the deep holes is isometric to the affine Dynkin diagram of the corresponding Niemeier lattice.
The Leech lattice has a density of . showed that it gives the densest lattice packing of balls in 24-dimensional space. improved this by showing that it is the densest sphere packing, even among non-lattice packings.
The 196560 minimal vectors are of three different varieties, known as shapes:
The ternary Golay code, binary Golay code, and Leech lattice give very efficient 24-dimensional spherical codes of 729, 4096, and 196560 points, respectively. Spherical codes are higher-dimensional analogues of Tammes problem, which arose as an attempt to explain the distribution of pores on pollen grains. These are distributed as to maximise the minimal angle between them. In two dimensions, the problem is trivial, but in three dimensions and higher it is not. An example of a spherical code in three dimensions is the set of the 12 vertices of the regular icosahedron.
One can associate to any (positive-definite) lattice ÃÂ a theta function given by
The theta function of a lattice is then a holomorphic function on the upper half-plane. Furthermore, the theta function of an even unimodular lattice of rank n is actually a modular form of weight n/2 for the full modular group PSL(2,Z). The theta function of an integral lattice is often written as a power series in so that the coefficient of q<sup>n</sup> gives the number of lattice vectors of squared norm 2n. In the Leech lattice, there are 196560 vectors of squared norm 4, vectors of squared norm 6, vectors of squared norm 8, and so on. The theta series of the Leech lattice is
where is the normalized Eisenstein series of weight 12, is the modular discriminant, is the divisor function for exponent 11, and is the Ramanujan tau function. It follows that for m âÂÂ¥ 1, the number of vectors of squared norm 2m is
Many of the cross-sections of the Leech lattice, including the Coxeter–Todd lattice and Barnes–Wall lattice, in 12 and 16 dimensions, were found much earlier than the Leech lattice. discovered a related odd unimodular lattice in 24 dimensions, now called the odd Leech lattice, one of whose two even neighbors is the Leech lattice. The Leech lattice was discovered in 1965 by , by improving some earlier sphere packings he found .
calculated the order of the automorphism group of the Leech lattice, and, working with John G. Thompson, discovered three new sporadic groups as a by-product: the Conway groups, Co<sub>1</sub>, Co<sub>2</sub>, Co<sub>3</sub>. They also showed that four other (then) recently announced sporadic groups, namely, Higman-Sims, Suzuki, McLaughlin, and the Janko group J<sub>2</sub>, could be found inside the Conway groups using the geometry of the Leech lattice. (Ronan, p. 155)
, has a single rather cryptic sentence mentioning that he found more than 10 even unimodular lattices in 24 dimensions without giving further details. stated that he found 9 of these lattices earlier in 1938, and found two more, the Niemeier lattice with A root system and the Leech lattice (and also the odd Leech lattice), in 1940.