leech lattice

In mathematics, the Leech lattice is a lattice Λ in R²⁴ discovered John Leech. It is the unique lattice with the following list of properties:

It is unimodular; i.e., it can be generated by the columns of a certain 24×24 matrix with determinant 1.
It is even; i.e., the square of the length of any vector in Λ is an even integer.
The shortest length of any non-zero vector in Λ is 2.

The last condition means that unit balls centered at the points of Λ 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 (compare with 6 in dimension 2, as the maximum number of pennies which can touch a central penny; see kissing number). It seems to be expected that this configuration also gives the densest packing of balls in 24-dimensional space, but this is still open. Cohn and Kumar showed that it is the densest lattice packing in 24-dimensional space. The Leech lattice can be explicitly constructed as the set of vectors of the form 2^−3/2(a₁, a₂, ..., a₂₄) where the a_i are integers such that

a_1+a_2+\cdots+a_{24}\equiv 4a_1\equiv 4a_2\equiv\cdots\equiv4a_{24}\pmod{8}

and the set of coordinates i such that a_i belongs to any fixed residue class (mod 4) is a word in the binary Golay code. The Leech lattice can also be constructed as

w^\perp/w

where w is the norm 0 vector

(0,1,2,3,...,22,23,24; 70)

in the 26 dimensional even Lorentzian unimodular lattice II_25,1. The Leech lattice is highly symmetrical. Its automorphism group is the double cover of the Conway group Co₁; its order is approximately 8.3×10¹⁸. Many other sporadic simple groups can be constructed as the stabilizers of various configurations of vectors in the Leech lattice. The covering radius of the Leech lattice is

\sqrt 2

; in other words, if we put a closed ball of this radius around each lattice point, then these just cover Euclidean space. The points at distance at least

\sqrt 2

from all lattice points are called the deep holes of the Leech lattice. There are 23 orbits of them, and they correspond to the 23 Niemeier lattices other than the Leech lattice. Conway showed that the Leech lattice is isometric to the Dynkin diagram of the reflection group of the 26 dimensional even Lorentzian unimodular lattice II_25,1.

References

Conway, J. H.; Sloane, N. J. A. (1999). Sphere packings, lattices and groups. (3rd ed.) With additional contributions by E. Bannai, R. E. Borcherds, J. Leech, S. P. Norton, A. M. Odlyzko, R. A. Parker, L. Queen and B. B. Venkov. Grundlehren der Mathematischen Wissenschaften, 290. New York: Springer-Verlag. ISBN 0-387-98585-9.
Leech, John, Canad. J. Math. 16 (1964).

<< Previous

Word Browser

Next >>

saturday night massacre
conrad of franconia
lublin voivodship
n pow
oath of allegiance
n affil
holm oak
cytogenetics
shannon whirry
canine
flora tristan

oregon white oak
turkey oak
boole's inequality
boxcar children
hms enterprise (1705)
hms enterprize (1709)
cork oak
gene stratton porter
skin walker
halley research station
list of ontario provincial highways

mechanical traveller
bchi automaton
julio cesar gonzalez
richard burns
neuroevolution of augmented topologies
hms enterprize (1718)
hms enterprize (1774)
carpatair
hms enterprise (1848)
list of optical topics
hms enterprise (1864)

hms enterprise (d52)
ernst august of hanover, 3rd duke of cumberland
hms enterprise (a71)
ji won kim
partial charge
advanced third reich
eliahu inbal
air moldova
latvians
moldavian airlines
hubert de givenchy

Leech Lattice

See also

References