Difference between revisions of "Completely-simple semi-group"
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− | One of the more important types of simple semi-groups. A semi-group | + | {{TEX|done}} |
+ | One of the more important types of simple semi-groups. A semi-group $S$ is called completely simple (completely $0$-simple) if it is simple ($0$-simple) and contains a primitive idempotent, i.e. a non-zero idempotent that is not an identity for any non-zero idempotent of $S$. If a zero is added to a completely-simple semi-group it becomes a completely $0$-simple semi-group; for this reason, many properties of completely-simple semi-groups may be deduced directly from the corresponding properties of completely $0$-simple semi-groups. | ||
− | A semi-group | + | A semi-group $S$ is completely $0$-simple if and only if it is $0$-simple and satisfies one of the following conditions: 1) $S$ has minimal non-zero left and right ideals; or 2) some power of each element of $S$ belongs to a subgroup of $S$. In particular, any periodic (and, a fortiori, finite) $0$-simple semi-group will be a completely $0$-simple semi-group. Any completely $0$-simple semi-group is an O-bisimple [[Regular semi-group|regular semi-group]] and is the union of its $0$-minimal left (right) ideals. A semi-group $S$ is a completely-simple semi-group if and only if it satisfies one of the following conditions: 1) $S$ is a rectangular band of isomorphic groups (cf. [[Band of semi-groups|Band of semi-groups]]); or 2) $S$ is regular and all its idempotents are primitive. A special kind of completely-simple semi-groups is the rectangular group which is the direct product of a group and a rectangular band (cf. [[Idempotents, semi-group of|Idempotents, semi-group of]]). A [[Right group|right group]] (left group) is in turn a special case of a rectangular semi-group. Rees' theorem gives an important representation of completely $0$-simple semi-groups: A semi-group is a completely $0$-simple semi-group if and only if it is isomorphic to a regular [[Rees semi-group of matrix type|Rees semi-group of matrix type]] over a group with zero. |
− | The study of finite completely-simple semi-groups formed the starting point of the development of the theory of semi-groups (cf. [[Semi-group|Semi-group]]). Completely | + | The study of finite completely-simple semi-groups formed the starting point of the development of the theory of semi-groups (cf. [[Semi-group|Semi-group]]). Completely $0$-simple and completely-simple semi-groups frequently appear in various theoretical investigations on semi-groups and are one of the most thoroughly studied types of semi-groups. |
====References==== | ====References==== | ||
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====Comments==== | ====Comments==== | ||
− | A semi-group | + | A semi-group $S$ is called simple ($0$-simple) if it has no proper ideals (respectively, if its only proper ideal is $\{0\}$ and $S^2\neq\{0\}$) (cf. [[Simple semi-group|Simple semi-group]]). More accurately, a primitive idempotent is a non-zero idempotent $e\in S$ such that for any non-zero idempotent $f\in S$, $fe=ef=f$ only if $f=e$ ( "e is not an identity for any f≠ e" ). |
A Rees semi-group of matrix type is often called a Rees matrix semi-group. | A Rees semi-group of matrix type is often called a Rees matrix semi-group. |
Latest revision as of 20:25, 14 April 2014
One of the more important types of simple semi-groups. A semi-group $S$ is called completely simple (completely $0$-simple) if it is simple ($0$-simple) and contains a primitive idempotent, i.e. a non-zero idempotent that is not an identity for any non-zero idempotent of $S$. If a zero is added to a completely-simple semi-group it becomes a completely $0$-simple semi-group; for this reason, many properties of completely-simple semi-groups may be deduced directly from the corresponding properties of completely $0$-simple semi-groups.
A semi-group $S$ is completely $0$-simple if and only if it is $0$-simple and satisfies one of the following conditions: 1) $S$ has minimal non-zero left and right ideals; or 2) some power of each element of $S$ belongs to a subgroup of $S$. In particular, any periodic (and, a fortiori, finite) $0$-simple semi-group will be a completely $0$-simple semi-group. Any completely $0$-simple semi-group is an O-bisimple regular semi-group and is the union of its $0$-minimal left (right) ideals. A semi-group $S$ is a completely-simple semi-group if and only if it satisfies one of the following conditions: 1) $S$ is a rectangular band of isomorphic groups (cf. Band of semi-groups); or 2) $S$ is regular and all its idempotents are primitive. A special kind of completely-simple semi-groups is the rectangular group which is the direct product of a group and a rectangular band (cf. Idempotents, semi-group of). A right group (left group) is in turn a special case of a rectangular semi-group. Rees' theorem gives an important representation of completely $0$-simple semi-groups: A semi-group is a completely $0$-simple semi-group if and only if it is isomorphic to a regular Rees semi-group of matrix type over a group with zero.
The study of finite completely-simple semi-groups formed the starting point of the development of the theory of semi-groups (cf. Semi-group). Completely $0$-simple and completely-simple semi-groups frequently appear in various theoretical investigations on semi-groups and are one of the most thoroughly studied types of semi-groups.
References
[1] | A.H. Clifford, G.B. Preston, "Algebraic theory of semi-groups" , 1–2 , Amer. Math. Soc. (1961–1967) |
[2] | E.S. Lyapin, "Semigroups" , Amer. Math. Soc. (1974) (Translated from Russian) |
[3] | K. Kapp, H. Schneider, "Completely 0-simple semigroups: an abstract treatment of the lattice of congruences" , Benjamin (1969) |
Comments
A semi-group $S$ is called simple ($0$-simple) if it has no proper ideals (respectively, if its only proper ideal is $\{0\}$ and $S^2\neq\{0\}$) (cf. Simple semi-group). More accurately, a primitive idempotent is a non-zero idempotent $e\in S$ such that for any non-zero idempotent $f\in S$, $fe=ef=f$ only if $f=e$ ( "e is not an identity for any f≠ e" ).
A Rees semi-group of matrix type is often called a Rees matrix semi-group.
References
[a1] | A.K. Suschkewitsch, "Ueber die endlichen Gruppen ohne das Gesetz der eindeutigen Umkehrbarkeit" Math. Ann. , 99 (1928) pp. 30–50 |
[a2] | D. Rees, "On semi-groups" Proc. Cambridge Phil. Soc. , 36 (1940) pp. 387–400 |
Completely-simple semi-group. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Completely-simple_semi-group&oldid=18594