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algebraic lattice
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(Definition)
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A lattice  is said to be an algebraic lattice if it is a complete lattice and every element of  can be written as a join of compact elements.
As the name (G. Birkhoff originally coined the term) suggests, algebraic lattices are mostly found in lattices of subalgebras of algebraic systems. Below are some common examples.
Examples.
- Groups. The lattice
 of subgroups of a group  is known to be complete. Cyclic subgroups are compact elements of  . Since every subgroup  of  is the join of cyclic subgroups, each generated by an element  ,  is algebraic.
- Vector spaces. The lattice
 of subspaces of a vector space  is complete. Since each subspace has a basis, and since each element generates a one-dimensional subspace which is clearly compact,  is algebraic.
- Rings. The lattice
 of ideals of a ring  is also complete, the join of a set of ideals of  is the ideal generated by elements in each of the ideals in the set. Any ideal  is the join of cyclic ideals generated by elements  . So  is algebraic.
- Modules. The above two examples can be combined and generalized into one, the lattice
 of submodules of a module  over a ring. The arguments are similar.
- Topological spaces. The lattice of closed subsets of a topological space is in general not algebraic. The simplest example is
 with the open intervals forming the subbasis. To begin with, it is not complete: the union of closed subsets
![$ [0,1-\frac{1}{n}]$](http://images.planetmath.org:8080/cache/objects/7951/l2h/img22.png "$ [0,1-\frac{1}{n}]$") ,
 is  , not a closed set. In addition,
 itself is a closed subset that is not compact.
Remarks.
- Since every element in an algebraic lattice is a join of compact elements, it is easy to see that every atom is compact: for if
 is an atom in an algebraic lattice  , and
 , where
 is a set of compact elements  , then each  is either 0 or  . Therefore,  consists of at most two elements 0 and  . But  can't be a singleton consisting of 0 (otherwise
 ), so  and therefore  is compact.
- The notion of being algebraic in a lattice can be generalized to an arbitrary dcpo: an algebraic dcpo is a dcpo
 such that every  can be written as
 , where  is a directed set (in  ) such that each element in  is compact.
- 1
- G. Birkhoff Lattice Theory, 3rd Edition, AMS Volume XXV, (1967).
- 2
- G. Grätzer, General Lattice Theory, 2nd Edition, Birkhäuser (1998).
- 3
- G. Gierz, K. H. Hofmann, K. Keimel, J. D. Lawson, M. W. Mislove, D. S. Scott, Continuous Lattices and Domains, Cambridge University Press, Cambridge (2003).
- 4
- S. Vickers, Topology via Logic, Cambridge University Press, Cambridge (1989).
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"algebraic lattice" is owned by CWoo.
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(view preamble)
See Also: sum of ideals
| Other names: |
compactly-generated lattice |
| Also defines: |
algebraic dcpo |
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Cross-references: directed set, dcpo, singleton, atom, easy to see, addition, union, subbasis, open intervals, closed subsets, topological spaces, similar, arguments, submodules, modules, cyclic, ideal generated by, ideals, rings, compact, generates, basis, subspaces, vector spaces, generated by, cyclic subgroups, complete, subgroups, groups, algebraic systems, subalgebras, algebraic, term, compact elements, join, complete lattice, lattice
There are 10 references to this entry.
This is version 11 of algebraic lattice, born on 2006-06-02, modified 2007-05-06.
Object id is 7951, canonical name is AlgebraicLattice.
Accessed 2146 times total.
Classification:
| AMS MSC: | 06B23 (Order, lattices, ordered algebraic structures :: Lattices :: Complete lattices, completions) |
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Pending Errata and Addenda
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