PSL(2,7): Difference between revisions

In mathematics, the projective special linear group PSL(2, 7), isomorphic to GL(3, 2), is a finite simple group that has important applications in algebra, geometry, and number theory. It is the automorphism group of the Klein quartic as well as the symmetry group of the Fano plane. With 168 elements, PSL(2, 7) is the smallest nonabelian simple group after the alternating group A₅ with 60 elements, isomorphic to PSL(2, 5).

The general linear group GL(2, 7) consists of all invertible 2×2 matrices over F₇, the finite field with 7 elements. These have nonzero determinant. The subgroup SL(2, 7) consists of all such matrices with unit determinant. Then PSL(2, 7) is defined to be the quotient group

SL(2, 7) / {I, −I}

obtained by identifying I and −I, where I is the identity matrix. In this article, we let G denote any group that is isomorphic to PSL(2, 7).

G = PSL(2, 7) has 168 elements. This can be seen by counting the possible columns; there are 7² − 1 = 48 possibilities for the first column, then 7² − 7 = 42 possibilities for the second column. We must divide by 7 − 1 = 6 to force the determinant equal to one, and then we must divide by 2 when we identify I and −I. The result is (48 × 42) / (6 × 2) = 168.

It is a general result that PSL(n, q) is simple for n, q ≥ 2 (q being some power of a prime number), unless (n, q) = (2, 2) or (2, 3). PSL(2, 2) is isomorphic to the symmetric group S₃, and PSL(2, 3) is isomorphic to alternating group A₄. In fact, PSL(2, 7) is the second smallest nonabelian simple group, after the alternating group A₅ = PSL(2, 5) = PSL(2, 4).

The number of conjugacy classes and irreducible representations is 6. The sizes of conjugacy classes are 1, 21, 42, 56, 24, 24. The dimensions of irreducible representations 1, 3, 3, 6, 7, 8.

Character table

${\displaystyle {\begin{array}{r|cccccc}&1A_{1}&2A_{21}&4A_{42}&3A_{56}&7A_{24}&7B_{24}\\\hline \chi _{1}&1&1&1&1&1&1\\\chi _{2}&3&-1&1&0&\sigma &{\bar {\sigma }}\\\chi _{3}&3&-1&1&0&{\bar {\sigma }}&\sigma \\\chi _{4}&6&2&0&0&-1&-1\\\chi _{5}&7&-1&-1&1&0&0\\\chi _{6}&8&0&0&-1&1&1\\\end{array}},}$

where

${\displaystyle \sigma ={\frac {-1+i{\sqrt {7}}}{2}}.}$

The following table describes the conjugacy classes in terms of the order of an element in the class, the size of the class, the minimum polynomial of every representative in GL(3, 2), and the function notation for a representative in PSL(2, 7). Note that the classes 7A and 7B are exchanged by an automorphism, so the representatives from GL(3, 2) and PSL(2, 7) can be switched arbitrarily.

The order of group is 168 = 3 × 7 × 8, this implies existence of Sylow's subgroups of orders 3, 7 and 8. It is easy to describe the first two, they are cyclic, since any group of prime order is cyclic. Any element of conjugacy class 3A₅₆ generates Sylow 3-subgroup. Any element from the conjugacy classes 7A₂₄, 7B₂₄ generates the Sylow 7-subgroup. The Sylow 2-subgroup is a dihedral group of order 8. It can be described as centralizer of any element from the conjugacy class 2A₂₁. In the GL(3, 2) representation, a Sylow 2-subgroup consists of the upper triangular matrices.

This group and its Sylow 2-subgroup provide a counter-example for various normal p-complement theorems for p = 2.

G = PSL(2, 7) acts via linear fractional transformation on the projective line P¹(7) over the field with 7 elements:

${\displaystyle {\text{For }}\gamma ={\begin{pmatrix}a&b\\c&d\end{pmatrix}}\in {\text{PSL}}(2,7){\text{ and }}x\in \mathbf {P} ^{1}\!(7),\ \gamma \cdot x={\frac {ax+b}{cx+d}}.}$

Every orientation-preserving automorphism of P¹(7) arises in this way, and so G = PSL(2, 7) can be thought of geometrically as a group of symmetries of the projective line P¹(7); the full group of possibly orientation-reversing projective linear automorphisms is instead the order 2 extension PGL(2, 7), and the group of collineations of the projective line is the complete symmetric group of the points.

However, PSL(2, 7) is also isomorphic to PSL(3, 2) (= SL(3, 2) = GL(3, 2)), the special (general) linear group of 3×3 matrices over the field with 2 elements. In a similar fashion, G = PSL(3, 2) acts on the projective plane P²(2) over the field with 2 elements — also known as the Fano plane:

For ${\displaystyle \gamma ={\begin{pmatrix}a&b&c\\d&e&f\\g&h&i\end{pmatrix}}\in {\text{PSL}}(3,2)\ \ }$ and ${\displaystyle \ \ \mathbf {x} ={\begin{pmatrix}x\\y\\z\end{pmatrix}}\in \mathbf {P} ^{2}\!(2),\ \ \gamma \ \cdot \ \mathbf {x} ={\begin{pmatrix}ax+by+cz\\dx+ey+fz\\gx+hy+iz\end{pmatrix}}}$

Again, every automorphism of P²(2) arises in this way, and so G = PSL(3, 2) can be thought of geometrically as the symmetry group of this projective plane. The Fano plane can be used to describe multiplication of octonions, so G acts on the set of octonion multiplication tables.

The Klein quartic is the projective variety over the complex numbers C defined by the quartic polynomial

x³y + y³z + z³x = 0.

It is a compact Riemann surface of genus g = 3, and is the only such surface for which the size of the conformal automorphism group attains the maximum of 84(g − 1). This bound is due to the Hurwitz automorphisms theorem, which holds for all g > 1. Such "Hurwitz surfaces" are rare; the next genus for which any exist is g = 7, and the next after that is g = 14.

As with all Hurwitz surfaces, the Klein quartic can be given a metric of constant negative curvature and then tiled with regular (hyperbolic) heptagons, as a quotient of the order-3 heptagonal tiling, with the symmetries of the surface as a Riemannian surface or algebraic curve exactly the same as the symmetries of the tiling. For the Klein quartic this yields a tiling by 24 heptagons, and the order of G is thus related to the fact that 24 × 7 = 168. Dually, it can be tiled with 56 equilateral triangles, with 24 vertices, each of degree 7, as a quotient of the order-7 triangular tiling.

Klein's quartic arises in many fields of mathematics, including representation theory, homology theory, octonion multiplication, Fermat's Last Theorem, and Stark's theorem on imaginary quadratic number fields of class number 1.

PSL(2, 7) is a maximal subgroup of the Mathieu group M₂₁; the groups M₂₁ and M₂₄ can be constructed as extensions of PSL(2, 7). These extensions can be interpreted in terms of the tiling of the Klein quartic, but are not realized by geometric symmetries of the tiling.^[1]

The group PSL(2, 7) acts on various finite sets:

• In its original interpretation as PSL(2, 7), orientation-preserving linear automorphisms of the projective line P¹(F₇), it acts transitively on the 8 points with a stabilizer of order 21 fixing a given point. It also acts 2-transitively with stabilizer of order 3 on each pair of points; and it has two orbits on triples of points, with trivial stabilizer on each triple. (The larger group PGL(2, 7) acts sharply 3-transitively.)
• Interpreted as PGL(3, 2), linear automorphisms of the Fano plane P²(F₂), it acts 2-transitively on the 7 points, with stabilizer of order 24 fixing each point, and stabilizer of order 4 fixing each pair of points.
• Interpreted as automorphisms of a tiling of the Klein quartic, it acts transitively on the 24 vertices (or dually, 24 heptagons), with stabilizer of order 7 (corresponding to a rotation about the vertex/heptagon).
• Interpreted as a subgroup of the Mathieu group M₂₁, the subgroup acts non-transitively on 21 points.

• Brown, Ezra; Loehr, Nicholas (2009). "Why is PSL (2,7)≅ GL (3,2)?" (PDF). Am. Math. Mon. 116 (8): 727–732. doi:10.4169/193009709X460859. Zbl 1229.20046. Archived from the original (PDF) on 2016-10-09. Retrieved 2014-09-27.

• The Eightfold Way: the Beauty of Klein's Quartic Curve (Silvio Levy, ed.)
• This Week's Finds in Mathematical Physics - Week 214 (John Baez)
• The Klein Quartic in Number Theory (Noam Elkies)
• Projective special linear group: PSL(3, 2)