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Evariste Galois (1811-1832)

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Title: Evariste Galois (1811-1832)


1
Evariste Galois (1811-1832)
  • 1827 developed interest for mathematics
  • 1828 failed the entrance exam to the Ecole
    Polytechnique, but continues to work on his own
  • 1829 first mathematics paper published on
    continued fractions in the Annales de
    mathématiques.
  • 25 May and 1 June he submitted articles on the
    algebraic solution of equations to the Académie
    des Sciences. Cauchy was appointed as referee of
    Galois' paper.
  • 1829 entered the Ecole Normale.
  • 1830 learned of a posthumous article by Abel
    which overlapped with a part of his work and
    submitted a new article On the condition that an
    equation be soluble by radicals in February. The
    paper was sent to Fourier, the secretary of the
    Academy, to be considered for the Grand Prize in
    mathematics. Fourier died in April 1830 and
    Galois' paper was never subsequently found and so
    never considered for the prize which went to Abel
    and Jacobi
  • 1830 He published three papers in Bulletin de
    Férussac.
  • 1830 Galois was invited by Poisson to submit a
    third version of his memoir on an equation
  • 1830 For writing a political letter Galois was
    expelled and he joined On 31 December 1830 the
    Artillery of the National Guard which was
    subsequently was abolished by Royal Decree since
    the new King Louis-Phillipe felt it was a threat
    to the throne.
  • 1830 In and out of prison
  • 1832 Galois contracted cholera during the Paris
    epidemic. He apparently fell in love with
    Stephanie-Felice du Motel, the daughter of the
    his physician
  • 1832 Galois fought a duel with Perscheux
    d'Herbinville on 30 May probably about Stephaine
    and subsequently died in Cochin hospital on 31
    May.
  • 1846 Liouville published the papers of Galois in
    his Journal.

2
The basic ideas of Galois Theory
  • Regard a polynomial equation f(x)0 with fixed
    the field K of coefficients!
  • In a field k one can add, subtract, multiply and
    divide just like in R, Q or C.
  • If f(x) has irreducible non-linear factors g(x),
    adjoin to K a root r of g(x) to obtain K(r),
    which is the field of rational functions in r
    with coefficients in K.
  • Check if f(x) still has irreducible non-linear
    factors. If this is so repeat 2.
  • End up with the splitting field L, which contains
    all roots of f and in which f factors completely.
  • Examples
  • f(x)x2-2 KQ.
  • This has no roots in Q.
  • Fix the root v2 and consider KQ(v2).
  • Now f(x)(x- v2)(x v2) and thus we are done KL
  • f(x)xp-1, p prime KQ.
  • This has the root 1 in Q. xp-1(x-1)g(x).
    Here g(x)1xx2xp-1 has no root in Q.
  • Fix a root z of g(x)(i.e. z s.t. zp1) and
    consider KQ(z).
  • Now f(x)(x-z) (x-z2) (x-zp-1)and thus we are
    done KL

3
The basic ideas of Galois Theory
  • Other examples
  • f(x)x3-2, KQ
  • There is no root in Q, so adjoin
    then in Q( ) f(x)(x- )(x2 x )
    i.e. f(x)(x- )g(x) with g(x)
    irreducible.
  • Adjoin a root z of g(x), z31. Then
    g(x)(x- )(x- )
    Now f(x) splits in LQ( , ) Q( , z)
  • f(x)x21, kR
  • No root in R, so adjoin a root i, to obtain
    x21(x-i)(xi) and LR(i)C.
  • Notice that if one adjoins a transcendental
    number like p then Q(p)Q(t), the rational
    functions in one variable.

4
The Galois resolvent
  • Galois showed that one can describe the splitting
    field L by adjoining only one root t of a
    different equation. LK(t).
  • To define a Galois resolvent of f(x) let a,b,c,
    be the roots of f(x) and LK(a,b,c,) the
    splitting field. Say f(x) has degree n, so that
    there are n roots. Consider TAUBVCW
    with integers
    A,B,C, and U,V,W, variables.
  • T is called a Galois resolvent if all the n!
    elements obtained by substituting the roots
    a,b,c, for the variables U,V,W, are distinct.
  • If t1, t2, t3, are the values of a Galois
    resolvent T then set F(X)(x- t1) (x- t2) (x-
    tn!)
  • Let t be a root of any irreducible factor G(X)
    over K of F(x), then LK(t).
  • Notice that if G(X) is Lagranges reduced
    equation and his program can be carried out if it
    is solvable.

5
Groups and Galois Theory
  • Consider the example 4 (f(x)(x21),KR, LC). We
    can interchange the solutions i and i. This is
    just complex conjugation, which is a field
    isomorphism, i.e. it respects addition and
    multiplication. Also the fixed elements of the
    complex conjugation are exactly KR.
  • In general there is a group which acts on L by
    field isomorphisms permuting the roots and fixing
    K. This is the Galois group.
  • To see this let t1,,tr be the roots of an
    irreducible factor G(x) of F(x) over K and let
    a1,..an be the roots of f(x) which are assumed to
    be all distinct.
  • ai lies in L, so aihi(t)
  • For any j h1(tj), , hn(tj) are also roots of
    f(x), so they are some permutation of the ai.
  • Now we get permutations by setting sj(ai)hi(tj)
  • These permutations give the Galois group.

6
Groups and solvability
  • In the step by step process, the group gets
    smaller in each step. Vice versa, the full group
    can be obtained in a step by step process from
    smaller groups.
  • The groups which one obtains by adjoining
    radicals are of a special type.
  • From these two observations Galois could give a
    criterion to say when an equation f(x) is soluble
    by radicals in terms of the Galois group.
    Technically if the group is solvable so is the
    equation.
  • Examples
  • For the general equation xnY1xn-1Y2xn-2
    Yn considered over K(Y1,,Yn) the
    Galois group is the group of all permutations of
    the numbers 1,,n and is not solvable for ngt4,
    hence there is no general formula for higher
    order equations
  • For the equation f(x)xn-1/(x-1), the group is
    the cyclic group of rotations of order n, which
    is solvable. So there is a formula in terms of
    radicals as Gauß had previously found. The group
    is the group of orientation preserving symmetries
    of a regular n-gon.
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