Towards the classification of symplectic linear quotient singularities admitting a symplectic resolution

@article{Bellamy2021TowardsTC,
  title={Towards the classification of symplectic linear quotient singularities admitting a symplectic resolution},
  author={Gwyn Bellamy and Johannes Schmitt and Ulrich Thiel},
  journal={Mathematische Zeitschrift},
  year={2021},
  volume={300},
  pages={661-681}
}
Over the past 2 decades, there has been much progress on the classification of symplectic linear quotient singularities V / G admitting a symplectic (equivalently, crepant) resolution of singularities. The classification is almost complete but there is an infinite series of groups in dimension 4—the symplectically primitive but complex imprimitive groups—and 10 exceptional groups up to dimension 10, for which it is still open. In this paper, we treat the remaining infinite series and prove that… 
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3 Citations

3 Citations

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References

SHOWING 1-10 OF 30 REFERENCES

On the (non)existence of symplectic resolutions of linear quotients

We study the existence of symplectic resolutions of quotient singularities V/GV/G, where VV is a symplectic vector space and GG acts symplectically. Namely, we classify the symplectically irreducible

Poisson deformations of symplectic quotient singularities

Symplectic resolutions for nilpotent orbits

Abstract.In this paper, firstly we calculate Picard groups of a nilpotent orbit 𝒪 in a classical complex simple Lie algebra and discuss the properties of being ℚ-factorial and factorial for the

On $81$ symplectic resolutions of a $4$-dimensional quotient by a group of order $32$

We provide a construction of 81 symplectic resolutions of a 4-dimensional quotient singularity obtained by an action of a group of order 32. The existence of such resolutions is known by a result of

Symplectic singularities

We introduce in this paper a particular class of rational singularities, which we call symplectic, and classify the simplest ones. Our motivation comes from the analogy between rational Gorenstein

ON SMOOTHNESS OF MINIMAL MODELS OF QUOTIENT SINGULARITIES BY FINITE SUBGROUPS OF SLn(ℂ)

Abstract We prove that a quotient singularity ℂn/G by a finite subgroup G ⊂ SLn(ℂ) has a crepant resolution only if G is generated by junior elements. This is a generalization of the result of

Holomorphic symplectic geometry and orbifold singularities

Let G be a finite group acting on a symplectic complex vector space V. Assume that the quotient V/G has a holomorphic symplectic resolution. We prove that G is generated by "symplectic

Poisson deformations of affine symplectic varieties

This is a continuation of math.AG/0609741. Let Y be an affine symplectic variety with a C^*-action with positive weights, and let \pi: X -> Y be its crepant resolution. Then \pi induces a natural map

Symplectic reflection algebras, Calogero-Moser space, and deformed Harish-Chandra homomorphism

Abstract.To any finite group Γ⊂Sp(V) of automorphisms of a symplectic vector space V we associate a new multi-parameter deformation, Hκ of the algebra ℂ[V]#Γ, smash product of Γ with the polynomial

On singular Calogero–Moser spaces

Using combinatorial properties of complex reflection groups we show that, if the group W is different from the wreath product 𝔖n≀Z/mZ and the binary tetrahedral group (labelled G(m, 1, n) and G4,