Small group number 4 of order 625

G is the group 625gp4

G has 2 minimal generators, rank 2 and exponent 25. The centre has rank 2.

The 6 maximal subgroups are: Ab(25,5) (6x).

There is one conjugacy class of maximal elementary abelian subgroups. Each maximal elementary abelian has rank 2.

This cohomology ring calculation is complete.

Ring structure

The cohomology ring has 4 generators:

• y₁ in degree 1, a nilpotent element
• y₂ in degree 1, a nilpotent element
• x₁ in degree 2, a regular element
• x₂ in degree 2, a regular element

There are 2 minimal relations:

• y₂² = 0
• y₁² = 0

This minimal generating set constitutes a Gröbner basis for the relations ideal.

Essential ideal: There is one minimal generator:

• y₁.y₂

Nilradical: There are 2 minimal generators:

• y₂
• y₁

Completion information

This cohomology ring was obtained from a calculation out to degree 4. The cohomology ring approximation is stable from degree 2 onwards, and Carlson's tests detect stability from degree 4 onwards.

This cohomology ring has dimension 2 and depth 2. Here is a homogeneous system of parameters:

• h₁ = x₁ in degree 2
• h₂ = x₂ in degree 2

The first 2 terms h₁, h₂ form a regular sequence of maximum length.

The first 2 terms h₁, h₂ form a complete Duflot regular sequence. That is, their restrictions to the greatest central elementary abelian subgroup form a regular sequence of maximal length.

The ideal of essential classes is free of rank 1 as a module over the polynomial algebra on h₁, h₂. These free generators are:

• G₁ = y₁.y₂ in degree 2

Koszul information

A basis for R/(h₁, h₂) is as follows. Carlson's Koszul condition stipulates that this must be confined to degrees less than 4.

• 1 in degree 0
• y₂ in degree 1
• y₁ in degree 1
• y₁.y₂ in degree 2

Restriction information

• Restrictions to maximal subgroups
• Restrictions to maximal elementary abelian subgroups
• Restriction to the greatest central elementary abelian subgroup

Restrictions to maximal subgroups

Restriction to maximal subgroup number 1, which is 125gp2

• y₁ restricts to 0
• y₂ restricts to y₁
• x₁ restricts to x₁
• x₂ restricts to x₂ - y₁.y₂

Restriction to maximal subgroup number 2, which is 125gp2

• y₁ restricts to y₁
• y₂ restricts to 0
• x₁ restricts to x₂
• x₂ restricts to x₁ + y₁.y₂

Restriction to maximal subgroup number 3, which is 125gp2

• y₁ restricts to - y₁
• y₂ restricts to y₁
• x₁ restricts to - x₂
• x₂ restricts to x₂ + x₁ - y₁.y₂

Restriction to maximal subgroup number 4, which is 125gp2

• y₁ restricts to 2y₁
• y₂ restricts to y₁
• x₁ restricts to 2x₂
• x₂ restricts to x₂ + x₁ + 2y₁.y₂

Restriction to maximal subgroup number 5, which is 125gp2

• y₁ restricts to y₁
• y₂ restricts to y₁
• x₁ restricts to x₂
• x₂ restricts to x₂ + x₁ + y₁.y₂

Restriction to maximal subgroup number 6, which is 125gp2

• y₁ restricts to - 2y₁
• y₂ restricts to y₁
• x₁ restricts to - 2x₂
• x₂ restricts to x₂ + x₁ - 2y₁.y₂

Restrictions to maximal elementary abelian subgroups

Restriction to maximal elementary abelian number 1, which is V25

• y₁ restricts to 0
• y₂ restricts to 0
• x₁ restricts to x₂ + x₁
• x₂ restricts to - x₂

Restriction to the greatest central elementary abelian subgroup

Restriction to the greatest central elementary abelian, which is V25

• y₁ restricts to 0
• y₂ restricts to 0
• x₁ restricts to - x₁
• x₂ restricts to x₂

Poincaré series

(1 + 2t + t²) / (1 - t²)²