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Symmetry and the Monster

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Title: Symmetry and the Monster


1
Symmetry and the Monster
  • One of the greatest quests in mathematics

2
A little early history
  • Equations of degree 2meaning the highest power
    of x is x2 solved by the Babylonians in about
    1800 BC
  • Equations of degree 3 solved using a graphical
    method by Omar Khayyám in about 1100 AD
  • Equations of degrees 3 and 4 solved by Italian
    mathematicians in the first half of the 1500s.

3
The quintic equation
  • Equations of degree 5 were a problem. No one
    could come up with a formula.
  • 1799 Paolo Ruffini
  • 1824 Niels Hendrik Abel
  • Early 1830s Évariste Galois

4
Galoiss Ideas
  • If the equation is irreducible any solution is
    equivalent to any other.
  • The solutions can be permuted among one another.
  • Not all permutations are possible, but those that
    are form the Galois group of the equation.

5
x4 - 10x2  1  0
  • There are four solutions, a, b, c, d
  • The negative of a solution is a solution, so we
    can set a  b  0, and c  d  0.
  • This restricts the possible permutationsif a
    goes to b then b goes to a, if a goes to c then b
    goes to d.

6
The Galois Group
  • Galois investigated when the solutions to a given
    equation can be expressed in terms of roots, and
    when they cant.
  • The solutions can be deconstructed into roots
    precisely when the Galois group can be
    deconstructed into cyclic groups.

7
Atoms of Symmetry
  • A group that cannot be deconstructed into simpler
    groups is called simple.
  • For each prime number p the group of rotations of
    a regular p-gon is simple it is a cyclic group.
  • The structure of a non-cyclic simple group can be
    very complex.

8
Families of Simple Groups
  • Galois discovered the first family of non-cyclic
    finite simple groups.
  • Other families were discovered in the later
    nineteenth century.
  • All these families were later seen as groups of
    Lie type, stemming from work of Sophus Lie.

9
Sophus Lie
  • Lie wanted to do for differential equations what
    Galois had done for algebraic equations.
  • He created the concept of continuous groups, now
    called Lie groups.
  • Simple Lie groups were classified into seven
    families, A to G, by Wilhelm Killing.

10
Finite groups of Lie type
  • Finite versions of Lie groups are called groups
    of Lie type.
  • Most of them were created by Leonard Dickson in
    1901.
  • In 1955 Claude Chevalley found a uniform method
    yielding all families A to G.
  • Variations on Chevalleys theme soon emerged, and
    by 1961 all finite groups of Lie type had been
    found.

11
The Feit-Thompson Theorem
  • In 1963, Walter Feit and John Thompson proved the
    following big theorem
  • A non-cyclic finite simple group must contain an
    element of order 2.
  • Elements of order 2 give rise to
    cross-sections, and Richard Brauer had shown
    that knowing one cross-section of a finite simple
    group gave a firm handle on the group itself.

12
The Classification
  • By 1965 it looked as if a finite simple group
    must be a group of Lie type, or one of five
    exceptions discovered in the mid-nineteenth
    century.
  • These five exceptions, the Mathieu groupscreated
    by Émile Mathieuare very exceptional. There is
    nothing else quite like them.

13
A Cat among the Pigeons
  • In 1966, Zvonimir Janko in Australia produced a
    sixth exception.
  • He discovered it via one of its cross-sections.
  • This led Janko and others to search for more
    exceptions, and within ten years another twenty
    turned up.

14
The Exceptions
  • Some were found using the cross-section method
  • Some were found by studying groups of
    permutations
  • Some were found using geometry

15
The Hall-Janko group J2
  • Janko found it using the cross-section method.
  • Marshall Hall found it using permutation groups.
  • Jacques Tits constructed it using geometry.

16
The Leech Lattice
  • John Leech used the largest Mathieu group M24 to
    create a remarkable lattice in 24 dimensions.
  • John Conway studied Leechs lattice and turned up
    three new exceptions.
  • Had he investigated it two years earlier, he
    would have found two morethe Leech Lattice
    contains half of the exceptional symmetry atoms.

17
Fischers Monsters
  • Bernd Fischer in Germany discovered three
    intriguing and very large permutation groups,
    modelled on the three largest Mathieu groups.
  • He then found a fourth one of a different type,
    and even larger, called the Baby Monster.
  • Using this as a cross-section, he turned up
    something even bigger, called the Monster.

18
Computer Constructions
  • When the exceptional groups were discovered, it
    was not always clear that they existed.
  • Proving existence could be tricky, and computers
    were sometimes used.
  • For example the Baby Monster was constructed on a
    computer.
  • BUT the Monster was too large for computer
    methods.

19
Constructing the Monster
  • Fischer, Livingstone and Thorne constructed the
    character table of the Monster, a 194-by-194
    array of numbers.
  • This showed the Monster could not live in fewer
    than 196,883 dimensions.
  • 196,883  47?59?71, the three largest primes
    dividing the size of the Monster.
  • Later Robert Griess constructed the Monster by
    hand in 196,884 dimensions.

20
McKays Observation
  • 196,883  1  196,884, the smallest non-trivial
    coefficient of the j-function.
  • McKay wrote to Thompson who had further data on
    the Monster available.
  • Thompson confirmed that other dimensions for the
    Monster seemed to be related to coefficients of
    the j-function.

21
Oggs Observation
  • Shortly after evidence for the Monster was
    announced, Andrew Ogg attended a lecture in
    Paris.
  • Jacques Tits wrote down the size of the Monster,
    as a product of prime numbers.
  • Ogg noticed these were precisely the primes that
    appeared in connection with his own work on the
    j-function.

22
Moonshine
  • The mysterious connections between the Monster
    and the j-function were dubbed Moonshine.
  • John Conway and Simon Norton investigated them in
    detail, proved they were real, and made
    conjectures about a deeper connection.
  • Their paper was called Monstrous Moonshine

23
Vertex Algebras and String Theory
  • The Moonshine connections involved the Monster
    acting in finite dimensional spaces.
  • Frenkel, Leopwski and Meurman combined these in
    an infinite dimensional space.
  • Their space had a vertex algebra structure, which
    brought in the mathematics of string theory.

24
Conway-Norton Conjectures
  • The conjectures by Conway and Norton were later
    proved by Richard Borcherds, who received a
    Fields Medal for his work,but as he points out,
    there are still mysteries to resolve
  • For example the space of j-functions associated
    with the Monster has dimension 163. Is this just
    a coincidence?
  • e?v163  262537412640768743.99999999999925... is
    very close to being a whole number.
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