Lattice of subgroups

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The lattice of subgroups of the dihedral group Dih₄, represented as groups of rotations and reflections of a plane figure. The lattice is shown as a Hasse diagram.

In mathematics, the lattice of subgroups of a group $G$ is the lattice whose elements are the subgroups of $G$ , with the partial order relation being set inclusion. In this lattice, the join of two subgroups is the subgroup generated by their union, and the meet of two subgroups is their intersection.

Lattice theoretic information about the lattice of subgroups can sometimes be used to infer information about the original group. For instance, a group is locally cyclic if and only if its lattice of subgroups is distributive.

1 Example
2 Characteristic lattices
3 See also
4 References
5 External links

[edit] Example

The dihedral group Dih₄ has ten subgroups, counting itself and the trivial subgroup. Five of the eight group elements generate subgroups of order two, and two others generate the same cyclic group C₄. In addition, there are two groups of the form C₂×C₂, generated by pairs of order-two elements. The lattice formed by these ten subgroups is shown in the illustration.

[edit] Characteristic lattices

Subgroups with certain properties form lattices, but other properties do not.

Nilpotent normal subgroups form a lattice, which is (part of) the content of Fitting's theorem.
In general, for any Fitting class F, both the subnormal F-subgroups and the normal F-subgroups form lattices. This includes the above with F the class of nilpotent groups, as well as other examples such as F the class of solvable groups. A class of groups is called a Fitting class if it is closed under isomorphism, subnormal subgroups, and products of subnormal subgroups.
Central subgroups form a lattice.

However, neither finite subgroups nor torsion subgroups form a lattice: for instance, the free product $\mathbf{Z}/2\mathbf{Z} * \mathbf{Z}/2\mathbf{Z}$ is generated by two torsion elements, but is infinite and contains elements of infinite order.

[edit] See also

Zassenhaus lemma, an isomorphism between certain quotients in the lattice of subgroups
Complemented group, a group with a complemented lattice of subgroups
Lattice theorem, a Galois connection between the lattice of subgroups of a group and of its quotient

[edit] References

Baer, Reinhold; Hausdorff, Felix (1939). "The significance of the system of subgroups for the structure of the group". American Journal of Mathematics 61 (1): 1–44. doi:10.2307/2371383.

Rottlaender, Ada (1928). "Nachweis der Existenz nicht-isomorpher Gruppen von gleicher Situation der Untergruppen". Mathematische Zeitschrift 28 (1): 641–653. doi:10.1007/BF01181188.

Schmidt, Roland (1994). Subgroup Lattices of Groups. Expositions in Math, vol. 14, de Gruyter. Review by Ralph Freese in Bull. AMS 33 (4): 487–492.

Suzuki, Michio (1951). "On the lattice of subgroups of finite groups". Transactions of the American Mathematical Society 70 (2): 345–371. doi:10.2307/1990375.

Suzuki, Michio (1956). Structure of a Group and the Structure of its Lattice of Subgroups. Berlin: Springer Verlag.

Yakovlev, B. V. (1974). "Conditions under which a lattice is isomorphic to a lattice of subgroups of a group". Algebra and Logic 13 (6). doi:10.1007/BF01462952.