Weyl Groups are Finite — and Other Finiteness Properties of Cartan Subalgebras
Identifieur interne : 001A45 ( Main/Merge ); précédent : 001A44; suivant : 001A46Weyl Groups are Finite — and Other Finiteness Properties of Cartan Subalgebras
Auteurs : Karl H. Hofmann ; Jimmie D. Lawson ; Wolfgang A. F. Ruppert [États-Unis]Source :
- Mathematische Nachrichten [ 0025-584X ] ; 1996.
English descriptors
- KwdEn :
- Abelian, Algebra, Algebraic, Algebraic group, Algebraic groups, Algebraic hull, Algebraic hull operator, Automorphism, Automorphisms, Cartan, Cartan algebra, Cartan algebras, Cartan subalgebra, Cartan subalgebras, Cartan subgroup, Cartan subgroups, Complex vector space, Equivalent conditions, Exponential, Exponential function, Finiteness, Finiteness theorems, Fitting decomposition, Inner automorphisms, Maximal rank, Morphism, Nachr, Nonzero roots, Normalizer, Reductively, Regular element, Regular elements, Root space, Root spaces, Semisimple, Solvable, Subalgebra, Subalgebras, Subgroup, Subset, Surjective, Weyl, Weyl group, Weyl groups, Zariski, Zariski closure.
- Teeft :
- Abelian, Algebra, Algebraic, Algebraic group, Algebraic groups, Algebraic hull, Algebraic hull operator, Automorphism, Automorphisms, Cartan, Cartan algebra, Cartan algebras, Cartan subalgebra, Cartan subalgebras, Cartan subgroup, Cartan subgroups, Complex vector space, Equivalent conditions, Exponential, Exponential function, Finiteness, Finiteness theorems, Fitting decomposition, Inner automorphisms, Maximal rank, Morphism, Nachr, Nonzero roots, Normalizer, Reductively, Regular element, Regular elements, Root space, Root spaces, Semisimple, Solvable, Subalgebra, Subalgebras, Subgroup, Subset, Surjective, Weyl, Weyl group, Weyl groups, Zariski, Zariski closure.
Abstract
For each pair (𝔤,𝔞) consisting of a real Lie algebra 𝔤 and a subalgebra a of some Cartan subalgebra 𝔥 of 𝔤 such that [𝔞, 𝔥]∪ [𝔞, 𝔞] we define a Weyl group W(𝔤, 𝔞) and show that it is finite. In particular, W(𝔤, 𝔥,) is finite for any Cartan subalgebra h. The proof involves the embedding of 0 into the Lie algebra of a complex algebraic linear Lie group to which the structure theory of Lie algebras and algebraic groups is applied. If G is a real connected Lie group with Lie algebra 𝔤, the normalizer N(𝔥, G) acts on the finite set Λ of roots of the complexification 𝔤c with respect to hc, giving a representation π : N(𝔥, G)→ S(Λ) into the symmetric group on the set Λ. We call the kernel of this map the Cartan subgroup C(𝔥) of G with respect to h; the image is isomorphic to W(𝔤, 𝔥), and C(𝔥)= {g G : Ad(g)(h)— h ε [h,h] for all h ε h }. All concepts introduced and discussed reduce in special situations to the familiar ones. The information on the finiteness of the Weyl groups is applied to show that under very general circumstance, for b ∪ 𝔥 the set 𝔥⊂ ϕ(b) remains finite as ϕ ranges through the full group of inner automorphisms of 𝔤.
Url:
DOI: 10.1002/mana.19961790109
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Hofmann</name><affiliation></affiliation><affiliation></affiliation><affiliation><wicri:noCountry code="no comma">E-mail: hofmann@mathemati K. Th‐darmstadT.de</wicri:noCountry></affiliation></author><author><name sortKey="Lawson, Jimmie D" sort="Lawson, Jimmie D" uniqKey="Lawson J" first="Jimmie D." last="Lawson">Jimmie D. Lawson</name><affiliation></affiliation><affiliation></affiliation><affiliation><wicri:noCountry code="no comma">E-mail: ruppert@mai L.boku.ac.at</wicri:noCountry></affiliation></author><author><name sortKey="Ruppert, Wolfgang A F" sort="Ruppert, Wolfgang A F" uniqKey="Ruppert W" first="Wolfgang A. F." last="Ruppert">Wolfgang A. F. Ruppert</name><affiliation></affiliation><affiliation wicri:level="1"><country xml:lang="fr">États-Unis</country><wicri:regionArea>Louisiana State University Department of Mathematics Baton Rouge</wicri:regionArea></affiliation><affiliation></affiliation></author></analytic><monogr></monogr><series><title level="j" type="main">Mathematische Nachrichten</title><title level="j" type="alt">MATHEMATISCHE NACHRICHTEN</title><idno type="ISSN">0025-584X</idno><idno type="eISSN">1522-2616</idno><imprint><biblScope unit="vol">179</biblScope><biblScope unit="issue">1</biblScope><biblScope unit="page" from="119">119</biblScope><biblScope unit="page" to="143">143</biblScope><biblScope unit="page-count">25</biblScope><publisher>WILEY‐VCH Verlag</publisher><pubPlace>Berlin</pubPlace><date type="published" when="1996">1996</date></imprint><idno type="ISSN">0025-584X</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0025-584X</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Abelian</term><term>Algebra</term><term>Algebraic</term><term>Algebraic group</term><term>Algebraic groups</term><term>Algebraic hull</term><term>Algebraic hull operator</term><term>Automorphism</term><term>Automorphisms</term><term>Cartan</term><term>Cartan algebra</term><term>Cartan algebras</term><term>Cartan subalgebra</term><term>Cartan subalgebras</term><term>Cartan subgroup</term><term>Cartan subgroups</term><term>Complex vector space</term><term>Equivalent conditions</term><term>Exponential</term><term>Exponential function</term><term>Finiteness</term><term>Finiteness theorems</term><term>Fitting decomposition</term><term>Inner automorphisms</term><term>Maximal rank</term><term>Morphism</term><term>Nachr</term><term>Nonzero roots</term><term>Normalizer</term><term>Reductively</term><term>Regular element</term><term>Regular elements</term><term>Root space</term><term>Root spaces</term><term>Semisimple</term><term>Solvable</term><term>Subalgebra</term><term>Subalgebras</term><term>Subgroup</term><term>Subset</term><term>Surjective</term><term>Weyl</term><term>Weyl group</term><term>Weyl groups</term><term>Zariski</term><term>Zariski closure</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Abelian</term><term>Algebra</term><term>Algebraic</term><term>Algebraic group</term><term>Algebraic groups</term><term>Algebraic hull</term><term>Algebraic hull operator</term><term>Automorphism</term><term>Automorphisms</term><term>Cartan</term><term>Cartan algebra</term><term>Cartan algebras</term><term>Cartan subalgebra</term><term>Cartan subalgebras</term><term>Cartan subgroup</term><term>Cartan subgroups</term><term>Complex vector space</term><term>Equivalent conditions</term><term>Exponential</term><term>Exponential function</term><term>Finiteness</term><term>Finiteness theorems</term><term>Fitting decomposition</term><term>Inner automorphisms</term><term>Maximal rank</term><term>Morphism</term><term>Nachr</term><term>Nonzero roots</term><term>Normalizer</term><term>Reductively</term><term>Regular element</term><term>Regular elements</term><term>Root space</term><term>Root spaces</term><term>Semisimple</term><term>Solvable</term><term>Subalgebra</term><term>Subalgebras</term><term>Subgroup</term><term>Subset</term><term>Surjective</term><term>Weyl</term><term>Weyl group</term><term>Weyl groups</term><term>Zariski</term><term>Zariski closure</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">For each pair (𝔤,𝔞) consisting of a real Lie algebra 𝔤 and a subalgebra a of some Cartan subalgebra 𝔥 of 𝔤 such that [𝔞, 𝔥]∪ [𝔞, 𝔞] we define a Weyl group W(𝔤, 𝔞) and show that it is finite. In particular, W(𝔤, 𝔥,) is finite for any Cartan subalgebra h. The proof involves the embedding of 0 into the Lie algebra of a complex algebraic linear Lie group to which the structure theory of Lie algebras and algebraic groups is applied. If G is a real connected Lie group with Lie algebra 𝔤, the normalizer N(𝔥, G) acts on the finite set Λ of roots of the complexification 𝔤c with respect to hc, giving a representation π : N(𝔥, G)→ S(Λ) into the symmetric group on the set Λ. We call the kernel of this map the Cartan subgroup C(𝔥) of G with respect to h; the image is isomorphic to W(𝔤, 𝔥), and C(𝔥)= {g G : Ad(g)(h)— h ε [h,h] for all h ε h }. All concepts introduced and discussed reduce in special situations to the familiar ones. The information on the finiteness of the Weyl groups is applied to show that under very general circumstance, for b ∪ 𝔥 the set 𝔥⊂ ϕ(b) remains finite as ϕ ranges through the full group of inner automorphisms of 𝔤.</div></front></TEI></record>Pour manipuler ce document sous Unix (Dilib)
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