Jacobson’s refinement of Engel’s theorem for Leibniz algebras

Bosko, Lindsey; Hedges, Allison; Hird, J. T.; Schwartz, Nathaniel; Stagg, Kristen

doi:10.2140/involve.2011.4.293

Cited by 23 publications

(18 citation statements)

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“…The second method greatly shortens the proof. The short proof given here shows the result using Lie sets and follows that in [12]. A Lie subset of a Leibniz algebra A is a subset that is closed under multiplication.…”

Section: For a Leibniz Algebra A The Series Of Idealssupporting

confidence: 53%

“…As an immediate consequence of Proposition 4.2, we have Several authors have given various forms of Engel's theorem for Leibniz algebras. The Leibniz versions were proven without using the standard Lie algebra result in [4] and [27], and using the standard result in [8] and [12]. The second method greatly shortens the proof.…”

Section: For a Leibniz Algebra A The Series Of Idealsmentioning

confidence: 99%

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On some structures of Leibniz algebras

Demir¹,

Misra²,

Stitzinger³

2014

Contemporary Mathematics

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Section: For a Leibniz Algebra A The Series Of Idealssupporting

confidence: 53%

Section: For a Leibniz Algebra A The Series Of Idealsmentioning

confidence: 99%

On some structures of Leibniz algebras

Demir¹,

Misra²,

Stitzinger³

2014

Contemporary Mathematics

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“…Thus, that nilpotency is 2-recognizeable in Leibniz algebras follows from all left multiplications being nilpotent, Engel's theorem. This result, shown in several places, can be cast as in Jacobson's refinement to Engel's theorem for Lie algebras, see [6], a result that we use.…”

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confidence: 81%

2-recognizeable classes of Leibniz algebras

et al. 2015

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We show that for fields that are of characteristic 0 or algebraically closed of characteristic greater than 5, that certain classes of Leibniz algebras are 2-recognizeable. These classes are solvable, strongly solvable and supersolvable. These same results hold in Lie algebras and in general for groups.Key Words: 2-recognizeable, strongly solvable, supersolvable, Leibniz algebras I. PRELIMINARIES A property of algebras is called n-recognizeable if whenever all the n generated subalgebras of algebra L have the property, then L also has the property. An analogous definition holds for classes of groups. In Lie algebras, nilpotency is 2-recognizeable due to Engel's theorem and the same holds for Leibniz algebras. For Lie algebras, solvability, strong solvability and supersolvability are 2-recognizeable when they are taken over a field of characteristic 0 or an algebraically closed field of characteristic greater than 5. These results are shown in [7] and [12] using different methods. The purpose of this work is to extend these results to Leibniz algebras. Corresponding results in group theory are shown in [8] and [9].The definition of Leibniz algebra can be given in terms of the left multiplications being derivations. A theme in this work is that assumptions will be given in terms of the left multiplications. Thus, that nilpotency is 2-recognizeable in Leibniz algebras follows from all left multiplications being nilpotent, Engel's theorem. This result, shown in several places, can be cast as in Jacobson's refinement to Engel's theorem for Lie algebras, see [6], a result that we use.

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“…Proof If L is nilpotent of length less than three, then the result holds by the previous theorem, so let L be nilpotent of As D in nilpotent, D ⊆ K, we show K is a Cartan subalgebra of L. Assume y ∈ N L (K), but y / ∈ K. Then xy ∈ K, but y / ∈ S x , so xy / ∈ S x , contradiction. So y ∈ K thus K is its own normalizer in L. K = K ∩ (D + N (L)) = D + (K ∩ N (L)), and since D is nilpotent by definition, and (K ∩ N (L)) is a nilpotent ideal of K, K is nilpotent by [4]. Now assume D is contained in two Cartan subalgebras of L, E 1 and E 2 .…”

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confidence: 99%

Conjugacy of Cartan Subalgebras in Solvable Leibniz Algebras and Real Leibniz Algebras

Stitzinger

White

2017

Algebr Represent Theor

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ABSTRACT. We extend conjugacy results from Lie algebras to their Leibniz algebra generalizations. The proofs in the Lie case depend on anti-commutativity. Thus it is necessary to find other paths in the Leibniz case. Some of these results involve Cartan subalgebras. Our results can be used to extend other results on Cartan subalgebras. We show an example here and others will be shown in future work.Keywords: Leibniz algebras, Conjugacy, Cartan subalgebras, maximal subalgebras MSC 2010: 17A32 A self-centralizing minimal ideal in a solvable Lie algebra is complemented and all complements are conjugate [1]. Such an algebra is called primitive. If the minimal ideal is not self-centralizing, then there is a bijection which assigns complements to their intersection with the centralizer [7]. Such an intersection is the core of the complement. Towers extended this result to show that maximal subalgebras are conjugate exactly when their cores coincide, with the additional condition at characteristic p that L 2 has nilpotency class less than p. Under this same condition, Cartan subalgebras are conjugate. We show these results hold for Leibniz algebras. The antisymmetry is used in the Lie algebra case, and so we amend the arguments in the Leibniz algebra case. We also show consequences for the conjugacy of Cartan subalgebras in solvable Lie algebras. We also consider conjugacy of Cartan subalgebras for real Leibniz algebras, obtaining an extension of a result of Barnes

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Jacobson’s refinement of Engel’s theorem for Leibniz algebras

Cited by 23 publications

References 4 publications

On some structures of Leibniz algebras

On some structures of Leibniz algebras

2-recognizeable classes of Leibniz algebras

Conjugacy of Cartan Subalgebras in Solvable Leibniz Algebras and Real Leibniz Algebras

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