# Difference between revisions of "Groups of order 5040"

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(Created page with "{{groups of order|5040}} ==Statistics at a glance== The number 5040 has the prime factorization: <math>\! 5040 = 2^4 \cdot 3^2 \cdot 5^1 \cdot 7^1 = 16 \cdot 9 \cdot 5 \cdo...") |
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| Number of non-solvable groups up to isomorphism || {{fillin}} || There are four possibilities for the simple non-abelian composition factor: [[alternating group:A7]] (order 2520), [[alternating group:A6]] (order 360), [[projective special linear group:PSL(3,2)]] (order 168), and [[alternating group:A5]] (order 60). For each choice of simple non-abelian composition factor, the other composition factors must be cyclic of prime order so that the product is the order of the group. | | Number of non-solvable groups up to isomorphism || {{fillin}} || There are four possibilities for the simple non-abelian composition factor: [[alternating group:A7]] (order 2520), [[alternating group:A6]] (order 360), [[projective special linear group:PSL(3,2)]] (order 168), and [[alternating group:A5]] (order 60). For each choice of simple non-abelian composition factor, the other composition factors must be cyclic of prime order so that the product is the order of the group. | ||

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+ | | Number of [[perfect group]]s up to isomorphism || 1 || [[double cover of alternating group:A7]] | ||

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| Number of simple groups up to isomorphism || 0 || | | Number of simple groups up to isomorphism || 0 || |

## Latest revision as of 20:42, 21 May 2012

## Contents |

This article gives information about, and links to more details on, groups of order 5040

See pages on algebraic structures of order 5040| See pages on groups of a particular order

## Statistics at a glance

The number 5040 has the prime factorization:

All groups of this order have not yet been classified. The information below is therefore partial.

Quantity | Value | Explanation |
---|---|---|

Total number of groups up to isomorphism | unknown, but likely between 500 and 10000 | |

Number of abelian groups (i.e., finite abelian groups) up to isomorphism | 10 | (Number of abelian groups of order ) times (Number of abelian groups of order ) times (Number of abelian groups of order ) times (Number of abelian groups of order ) = (number of unordered integer partitions of 4) times (number of unordered integer partitions of 2) times (number of unordered integer partitions of 1) times (number of unordered integer partitions of 1) = . See classification of finite abelian groups and structure theorem for finitely generated abelian groups. |

Number of nilpotent groups (i.e., finite nilpotent groups) up to isomorphism | 28 | (Number of groups of order 16) times (Number of groups of order 9) times (Number of groups of order 5) times (Number of groups of order 7) = . See number of nilpotent groups equals product of number of groups of order each maximal prime power divisor, which in turn follows from equivalence of definitions of finite nilpotent group. |

Number of solvable groups (i.e., finite solvable groups) up to isomorphism | unknown, but likely between 500 and 10000 | |

Number of non-solvable groups up to isomorphism | PLACEHOLDER FOR INFORMATION TO BE FILLED IN: [SHOW MORE] |
There are four possibilities for the simple non-abelian composition factor: alternating group:A7 (order 2520), alternating group:A6 (order 360), projective special linear group:PSL(3,2) (order 168), and alternating group:A5 (order 60). For each choice of simple non-abelian composition factor, the other composition factors must be cyclic of prime order so that the product is the order of the group. |

Number of perfect groups up to isomorphism | 1 | double cover of alternating group:A7 |

Number of simple groups up to isomorphism | 0 | |

Number of almost simple groups up to isomorphism | 1 | symmetric group:S7 |

Number of quasisimple groups up to isomorphism | 1 | double cover of alternating group:A7 |