A ''semisimple ring'' or '' Semisimple Algebra '' is one that is semisimple as a module over itself.
A ''semisimple'' Matrix (or Linear Transformation of Finite-dimensionalVector Space s) is one for which every Invariant Subspace has an invariant complement. This is equivalent to the Minimal Polynomial having only IrreducibleFactors with multiplicity one. Over a Perfect Field , this amounts to saying that the matrix has simple roots in the algebraic closure (or any larger algebraically closed field), i.e., it becomes Diagonalizable over the algebraic closure. Thus, over an algebraically closed field, “semisimple” and “diagonalizable” are synonymous for matrices.
A '' Semisimple Lie Algebra '' is a Lie Algebra which is a direct sum of Simple Lie Algebra s. A Lie algebra is simple if its dimension is larger than one and if it does not contain any nontrivial ideals. This means that if is such that for any if , then is either zero or the whole Lie algebra.
A connected Lie Group is called ''semisimple'' when its Lie algebra is; and the same for Algebraic Group s. Every finite dimensional representation of a semisimple Lie algebra, Lie group, or algebraic group in Characteristic 0 is semisimple, i.e., completely reducible, but the converse is not true. (See Reductive Group .) Moreover, in characteristic ''p''>0, semisimple Lie groups and Lie algebras have finite dimensional representations that are not semisimple. An element of a semisimple Lie group or Lie algebra is itself ''semisimple'' if its image in every finite-dimensional representation is semisimple in the sense of matrices.
A Linear Algebraic Group ''G'' is called ''semisimple'' if the Radical of the Identity Component ''G0'' of ''G'' is trivial. ''G'' is semisimple if and only if ''G'' has no nontrivial connected abelian normal subgroup.
