In the mathematical field of order theory, an element ''a'' of a partially ordered set with least element '''0''' is an '''atom''' if '''0''' < ''a'' and there is no ''x'' such that '''0''' < ''x'' < ''a''.

Equivalently, one may define an atom to be an element that is minimal among the non-zero elements, or alternatively an element that covers the least element '''0'''.

==Atomic orderings== {| style="float:right" | [[File:Lattice T 4.svg|thumb|500x150px|'''Fig.&nbsp;2''': The lattice of divisors of 4, with the ordering "''is divisor of''", is atomic, with 2 being the only atom and coatom. It is not atomistic, since 4 cannot be obtained as least common multiple of atoms.]] |} {| style="float:right" | [[File:Hasse diagram of powerset of 3.svg|thumb|x150px|'''Fig.&nbsp;1''': The power set of the set {''x'', ''y'', ''z''} with the ordering "''is subset of''" is an atomistic partially ordered set: each member set can be obtained as the union of all singleton sets below it.]] |} Let <: denote the covering relation in a partially ordered set.

A partially ordered set with a least element '''0''' is '''atomic''' if every element ''b''&nbsp;>&nbsp;'''0''' has an atom ''a'' below it, that is, there is some ''a'' such that ''b''&nbsp;≥&nbsp;''a''&nbsp;:>&nbsp;''0''. Every finite partially ordered set with '''0''' is atomic, but the set of nonnegative real numbers (ordered in the usual way) is not atomic (and in fact has no atoms).

A partially ordered set is '''relatively atomic''' (or ''strongly atomic'') if for all ''a''&nbsp;<&nbsp;''b'' there is an element ''c'' such that ''a''&nbsp;<:&nbsp;''c''&nbsp;≤&nbsp;''b'' or, equivalently, if every interval [''a'',&nbsp;''b''] is atomic. Every relatively atomic partially ordered set with a least element is atomic. Every finite poset is relatively atomic.

A partially ordered set with least element '''0''' is called '''atomistic''' (not to be confused with '''atomic''') if every element is the least upper bound of a set of atoms. The linear order with three elements is not atomistic (see Fig.&nbsp;2).

Atoms in partially ordered sets are abstract generalizations of singleton sets in set theory (see Fig.&nbsp;1). Atomicity (the property of being atomic) provides an abstract generalization in the context of order theory of the ability to select an element from a non-empty set.

==Coatoms== The terms ''coatom'', ''coatomic'', and ''coatomistic'' are defined dually. Thus, in a partially ordered set with greatest element '''1''', one says that * a '''coatom''' is an element covered by '''1''', * the set is '''coatomic''' if every ''b''&nbsp;<&nbsp;'''1''' has a coatom ''c'' above it, and * the set is '''coatomistic''' if every element is the greatest lower bound of a set of coatoms.

==References== * {{Citation | last1=Davey | first1=B. A. | last2=Priestley | first2=H. A. |author2link = Hilary Priestley| title=Introduction to Lattices and Order|title-link= Introduction to Lattices and Order | publisher=Cambridge University Press | isbn=978-0-521-78451-1 | year=2002}}

==External links== * {{planetmath reference|urlname=Atom|title=Atom}} * {{planetmath reference|urlname=Poset|title=Poset}}

Category:Order theory