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Magma
magma: G := TransitiveGroup(25, 24);
Group action invariants
Degree $n$: | $25$ | magma: t, n := TransitiveGroupIdentification(G); n;
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Transitive number $t$: | $24$ | magma: t, n := TransitiveGroupIdentification(G); t;
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Group: | $C_5^2:C_{10}$ | ||
Parity: | $1$ | magma: IsEven(G);
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Primitive: | no | magma: IsPrimitive(G);
| magma: NilpotencyClass(G);
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$\card{\Aut(F/K)}$: | $1$ | magma: Order(Centralizer(SymmetricGroup(n), G));
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Generators: | (1,11,9,23,19,5,14,10,24,17)(2,13,8,22,16,4,12,6,25,20)(3,15,7,21,18), (1,6,17,13,24)(2,10,19,11,25)(3,9,16,14,21)(4,8,18,12,22)(5,7,20,15,23) | magma: Generators(G);
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Low degree resolvents
|G/N| Galois groups for stem field(s) $2$: $C_2$ $5$: $C_5$ $10$: $D_{5}$, $C_{10}$ $50$: $D_5\times C_5$ Resolvents shown for degrees $\leq 47$
Subfields
Degree 5: $C_5$
Low degree siblings
25T23Siblings are shown with degree $\leq 47$
A number field with this Galois group has no arithmetically equivalent fields.
Conjugacy classes
Cycle Type | Size | Order | Representative |
$ 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 $ | $1$ | $1$ | $()$ |
$ 5, 5, 5, 5, 1, 1, 1, 1, 1 $ | $10$ | $5$ | $( 6, 7, 8, 9,10)(11,12,13,14,15)(16,17,18,19,20)(21,22,23,24,25)$ |
$ 5, 5, 5, 5, 1, 1, 1, 1, 1 $ | $10$ | $5$ | $( 6, 8,10, 7, 9)(11,13,15,12,14)(16,18,20,17,19)(21,23,25,22,24)$ |
$ 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 1, 1, 1, 1, 1 $ | $25$ | $2$ | $( 2, 5)( 3, 4)( 7,10)( 8, 9)(12,15)(13,14)(17,20)(18,19)(22,25)(23,24)$ |
$ 5, 5, 5, 5, 5 $ | $2$ | $5$ | $( 1, 2, 3, 4, 5)( 6,10, 9, 8, 7)(11,14,12,15,13)(16,18,20,17,19) (21,22,23,24,25)$ |
$ 5, 5, 5, 5, 5 $ | $2$ | $5$ | $( 1, 3, 5, 2, 4)( 6, 9, 7,10, 8)(11,12,13,14,15)(16,20,19,18,17) (21,23,25,22,24)$ |
$ 10, 10, 5 $ | $25$ | $10$ | $( 1, 6,16,11,21)( 2, 7,18,13,22, 5,10,19,14,25)( 3, 8,20,15,23, 4, 9,17,12,24)$ |
$ 5, 5, 5, 5, 5 $ | $5$ | $5$ | $( 1, 6,16,11,21)( 2,10,18,14,22)( 3, 9,20,12,23)( 4, 8,17,15,24) ( 5, 7,19,13,25)$ |
$ 5, 5, 5, 5, 5 $ | $10$ | $5$ | $( 1, 6,17,13,24)( 2,10,19,11,25)( 3, 9,16,14,21)( 4, 8,18,12,22) ( 5, 7,20,15,23)$ |
$ 5, 5, 5, 5, 5 $ | $10$ | $5$ | $( 1, 6,18,15,22)( 2,10,20,13,23)( 3, 9,17,11,24)( 4, 8,19,14,25) ( 5, 7,16,12,21)$ |
$ 10, 10, 5 $ | $25$ | $10$ | $( 1,11, 6,21,16)( 2,13,10,25,18, 5,14, 7,22,19)( 3,15, 9,24,20, 4,12, 8,23,17)$ |
$ 5, 5, 5, 5, 5 $ | $5$ | $5$ | $( 1,11, 6,21,16)( 2,14,10,22,18)( 3,12, 9,23,20)( 4,15, 8,24,17) ( 5,13, 7,25,19)$ |
$ 5, 5, 5, 5, 5 $ | $10$ | $5$ | $( 1,11, 8,25,17)( 2,14, 7,21,19)( 3,12, 6,22,16)( 4,15,10,23,18) ( 5,13, 9,24,20)$ |
$ 5, 5, 5, 5, 5 $ | $10$ | $5$ | $( 1,11,10,24,18)( 2,14, 9,25,20)( 3,12, 8,21,17)( 4,15, 7,22,19) ( 5,13, 6,23,16)$ |
$ 5, 5, 5, 5, 5 $ | $5$ | $5$ | $( 1,16,21, 6,11)( 2,18,22,10,14)( 3,20,23, 9,12)( 4,17,24, 8,15) ( 5,19,25, 7,13)$ |
$ 5, 5, 5, 5, 5 $ | $10$ | $5$ | $( 1,16,25, 9,13)( 2,18,21, 8,11)( 3,20,22, 7,14)( 4,17,23, 6,12) ( 5,19,24,10,15)$ |
$ 5, 5, 5, 5, 5 $ | $10$ | $5$ | $( 1,16,24, 7,15)( 2,18,25, 6,13)( 3,20,21,10,11)( 4,17,22, 9,14) ( 5,19,23, 8,12)$ |
$ 10, 10, 5 $ | $25$ | $10$ | $( 1,16,21, 6,11)( 2,19,22, 7,14, 5,18,25,10,13)( 3,17,23, 8,12, 4,20,24, 9,15)$ |
$ 5, 5, 5, 5, 5 $ | $5$ | $5$ | $( 1,21,11,16, 6)( 2,22,14,18,10)( 3,23,12,20, 9)( 4,24,15,17, 8) ( 5,25,13,19, 7)$ |
$ 5, 5, 5, 5, 5 $ | $10$ | $5$ | $( 1,21,13,20, 7)( 2,22,11,17, 6)( 3,23,14,19,10)( 4,24,12,16, 9) ( 5,25,15,18, 8)$ |
$ 5, 5, 5, 5, 5 $ | $10$ | $5$ | $( 1,21,15,19, 8)( 2,22,13,16, 7)( 3,23,11,18, 6)( 4,24,14,20,10) ( 5,25,12,17, 9)$ |
$ 10, 10, 5 $ | $25$ | $10$ | $( 1,21,11,16, 6)( 2,25,14,19,10, 5,22,13,18, 7)( 3,24,12,17, 9, 4,23,15,20, 8)$ |
magma: ConjugacyClasses(G);
Group invariants
Order: | $250=2 \cdot 5^{3}$ | magma: Order(G);
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Cyclic: | no | magma: IsCyclic(G);
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Abelian: | no | magma: IsAbelian(G);
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Solvable: | yes | magma: IsSolvable(G);
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Nilpotency class: | not nilpotent | ||
Label: | 250.5 | magma: IdentifyGroup(G);
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Character table: not available. |
magma: CharacterTable(G);