- Source: Local Langlands conjectures
In mathematics, the local Langlands conjectures, introduced by Robert Langlands (1967, 1970), are part of the Langlands program. They describe a correspondence between the complex representations of a reductive algebraic group G over a local field F, and representations of the Langlands group of F into the L-group of G. This correspondence is not a bijection in general. The conjectures can be thought of as a generalization of local class field theory from abelian Galois groups to non-abelian Galois groups.
Local Langlands conjectures for GL1
The local Langlands conjectures for GL1(K) follow from (and are essentially equivalent to) local class field theory. More precisely the Artin map gives an isomorphism from the group GL1(K)= K* to the abelianization of the Weil group. In particular irreducible smooth representations of GL1(K) are 1-dimensional as the group is abelian, so can be identified with homomorphisms of the Weil group to GL1(C). This gives the Langlands correspondence between homomorphisms of the Weil group to GL1(C) and
irreducible smooth representations of GL1(K).
Representations of the Weil group
Representations of the Weil group do not quite correspond to irreducible smooth representations of general linear groups. To get a bijection, one has to slightly modify the notion of a representation of the Weil group, to something called a Weil–Deligne representation. This consists of a representation of the Weil group on a vector space V together with a nilpotent endomorphism N of V such that wNw−1=||w||N, or equivalently a representation of the Weil–Deligne group. In addition the representation of the Weil group should have an open kernel, and should be (Frobenius) semisimple.
For every Frobenius semisimple complex n-dimensional Weil–Deligne representation ρ of the Weil group of F there is an L-function L(s,ρ) and a local ε-factor ε(s,ρ,ψ) (depending on a character ψ of F).
Representations of GLn(F)
The representations of GLn(F) appearing in the local Langlands correspondence are smooth irreducible complex representations.
"Smooth" means that every vector is fixed by some open subgroup.
"Irreducible" means that the representation is nonzero and has no subrepresentations other than 0 and itself.
Smooth irreducible complex representations are automatically admissible.
The Bernstein–Zelevinsky classification reduces the classification of irreducible smooth representations to cuspidal representations.
For every irreducible admissible complex representation π there is an L-function L(s,π) and a local ε-factor ε(s,π,ψ) (depending on a character ψ of F). More generally, if there are two irreducible admissible representations π and π' of general linear groups there are local Rankin–Selberg convolution L-functions L(s,π×π') and ε-factors ε(s,π×π',ψ).
Bushnell & Kutzko (1993) described the irreducible admissible representations of general linear groups over local fields.
Local Langlands conjectures for GL2
The local Langlands conjecture for GL2 of a local field says that there is a (unique) bijection π from 2-dimensional semisimple Weil-Deligne representations of the Weil group to irreducible smooth representations of GL2(F) that preserves L-functions, ε-factors, and commutes with twisting by characters of F*.
Jacquet & Langlands (1970) verified the local Langlands conjectures for GL2 in the case when the residue field does not have characteristic 2. In this case the representations of the Weil group are all of cyclic or dihedral type. Gelfand & Graev (1962) classified the smooth irreducible representations of GL2(F) when F has odd residue characteristic (see also (Gelfand, Graev & Pyatetskii-Shapiro 1969, chapter 2)), and claimed incorrectly that the classification for even residue characteristic differs only insignifictanly from the odd residue characteristic case.
Weil (1974) pointed out that when the residue field has characteristic 2, there are some extra exceptional 2-dimensional representations of the Weil group whose image in PGL2(C) is of tetrahedral or octahedral type. (For global Langlands conjectures, 2-dimensional representations can also be of icosahedral type, but this cannot happen in the local case as the Galois groups are solvable.)
Tunnell (1978) proved the local Langlands conjectures for the general linear group GL2(K) over the 2-adic numbers, and over local fields containing a cube root of unity.
Kutzko (1980, 1980b) proved the local Langlands conjectures for the general linear group GL2(K) over all local fields.
Cartier (1981) and Bushnell & Henniart (2006) gave expositions of the proof.
Local Langlands conjectures for GLn
The local Langlands conjectures for general linear groups state that there are unique bijections π ↔ ρπ from equivalence classes of irreducible admissible representations π of GLn(F) to equivalence classes of continuous Frobenius semisimple complex n-dimensional Weil–Deligne representations ρπ of the Weil group of F, that preserve L-functions and ε-factors of pairs of representations, and coincide with the Artin map for 1-dimensional representations. In other words,
L(s,ρπ⊗ρπ') = L(s,π×π')
ε(s,ρπ⊗ρπ',ψ) = ε(s,π×π',ψ)
Laumon, Rapoport & Stuhler (1993) proved the local Langlands conjectures for the general linear group GLn(K) for positive characteristic local fields K. Carayol (1992) gave an exposition of their work.
Harris & Taylor (2001) proved the local Langlands conjectures for the general linear group GLn(K) for characteristic 0 local fields K. Henniart (2000) gave another proof. Carayol (2000) and Wedhorn (2008) gave expositions of their work.
Local Langlands conjectures for other groups
Borel (1979) and Vogan (1993) discuss the Langlands conjectures for more general groups. The Langlands conjectures for arbitrary reductive groups G are more complicated to state than the ones for general linear groups, and it is unclear what the best way of stating them should be. Roughly speaking, admissible representations of a reductive group are grouped into disjoint finite sets called L-packets, which should correspond to some classes of homomorphisms, called L-parameters, from the local Langlands group to the L-group of G. Some earlier versions used the Weil−Deligne group or the Weil group instead of the local Langlands group, which gives a slightly weaker form of the conjecture.
Langlands (1989) proved the Langlands conjectures for groups over the archimedean local fields R and C by giving the Langlands classification of their irreducible admissible representations (up to infinitesimal equivalence), or, equivalently, of their irreducible
(
g
,
K
)
{\displaystyle ({\mathfrak {g}},K)}
-modules.
Gan & Takeda (2011) proved the local Langlands conjectures for the symplectic similitude group GSp(4) and used that in Gan & Takeda (2010) to deduce it for the symplectic group Sp(4).
References
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Bushnell, Colin J.; Henniart, Guy (2006), The local Langlands conjecture for GL(2), Grundlehren der Mathematischen Wissenschaften [Fundamental Principles of Mathematical Sciences], vol. 335, Berlin, New York: Springer-Verlag, doi:10.1007/3-540-31511-X, ISBN 978-3-540-31486-8, MR 2234120
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Gelfand, I. M.; Graev, M. I.; Pyatetskii-Shapiro, I. I. (1969) [1966], Representation theory and automorphic functions, Generalized functions, vol. 6, Philadelphia, Pa.: W. B. Saunders Co., ISBN 978-0-12-279506-0, MR 0220673
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Kutzko, Philip (1980), "The Langlands conjecture for GL2 of a local field", Bulletin of the American Mathematical Society, New Series, 2 (3): 455–458, doi:10.1090/S0273-0979-1980-14765-5, ISSN 0002-9904, MR 0561532
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Langlands, Robert P. (1989) [1973], "On the classification of irreducible representations of real algebraic groups", in Sally, Paul J.; Vogan, David A. (eds.), Representation theory and harmonic analysis on semisimple Lie groups, Math. Surveys Monogr., vol. 31, Providence, R.I.: American Mathematical Society, pp. 101–170, ISBN 978-0-8218-1526-7, MR 1011897
Laumon, G.; Rapoport, M.; Stuhler, U. (1993), "D-elliptic sheaves and the Langlands correspondence", Inventiones Mathematicae, 113 (2): 217–338, Bibcode:1993InMat.113..217L, doi:10.1007/BF01244308, ISSN 0020-9910, MR 1228127, S2CID 124557672
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Vogan, David A. (1993), "The local Langlands conjecture", in Adams, Jeffrey; Herb, Rebecca; Kudla, Stephen; Li, Jian-Shu; Lipsman, Ron; Rosenberg, Jonathan (eds.), Representation theory of groups and algebras, Contemp. Math., vol. 145, Providence, R.I.: American Mathematical Society, pp. 305–379, ISBN 978-0-8218-5168-5, MR 1216197
Wedhorn, Torsten (2008), "The local Langlands correspondence for GL(n) over p-adic fields" (PDF), in Göttsche, Lothar; Harder, G.; Raghunathan, M. S. (eds.), School on Automorphic Forms on GL(n), ICTP Lect. Notes, vol. 21, Abdus Salam Int. Cent. Theoret. Phys., Trieste, pp. 237–320, arXiv:math/0011210, Bibcode:2000math.....11210W, ISBN 978-92-95003-37-8, MR 2508771, archived from the original (PDF) on 2020-05-07
Weil, André (1974), "Exercices dyadiques", Inventiones Mathematicae, 27 (1–2): 1–22, Bibcode:1974InMat..27....1W, doi:10.1007/BF01389962, ISSN 0020-9910, MR 0379445, S2CID 189830448
External links
Harris, Michael (2000), The local Langlands correspondence (PDF), Notes of (half) a course at the IHP
The work of Robert Langlands
Automorphic Forms - The local Langlands conjecture Lecture by Richard Taylor
Kata Kunci Pencarian:
- Daftar masalah matematika yang belum terpecahkan
- Local Langlands conjectures
- Langlands program
- Robert Langlands
- Geometric Langlands correspondence
- Local class field theory
- Lafforgue's theorem
- Richard Taylor (mathematician)
- Arithmetic geometry
- Fundamental lemma (Langlands program)
- Gan–Gross–Prasad conjecture