ADE classification


In mathematics, the ADE classification is a situation where certain kinds of objects are in correspondence with simply laced Dynkin diagrams. The question of giving a common origin to these classifications, rather than a posteriori verification of a parallelism, was posed in. The complete list of simply laced Dynkin diagrams comprises
Here "simply laced" means that there are no multiple edges, which corresponds to all simple roots in the root system forming angles of or . These are two of the four families of Dynkin diagrams, and three of the five exceptional Dynkin diagrams.
This list is non-redundant if one takes for If one extends the families to include redundant terms, one obtains the exceptional isomorphisms
and corresponding isomorphisms of classified objects.
The A, D, E nomenclature also yields the simply laced finite Coxeter groups, by the same diagrams: in this case the Dynkin diagrams exactly coincide with the Coxeter diagrams, as there are no multiple edges.

Lie algebras

In terms of complex semisimple Lie algebras:
In terms of compact Lie algebras and corresponding simply laced Lie groups:
The same classification applies to discrete subgroups of, the binary polyhedral groups; properly, binary polyhedral groups correspond to the simply laced affine Dynkin diagrams and the representations of these groups can be understood in terms of these diagrams. This connection is known as the after John McKay. The connection to Platonic solids is described in. The correspondence uses the construction of McKay graph.
Note that the ADE correspondence is not the correspondence of Platonic solids to their reflection group of symmetries: for instance, in the ADE correspondence the tetrahedron, cube/octahedron, and dodecahedron/icosahedron correspond to while the reflection groups of the tetrahedron, cube/octahedron, and dodecahedron/icosahedron are instead representations of the Coxeter groups and
The orbifold of constructed using each discrete subgroup leads to an ADE-type singularity at the origin, termed a du Val singularity.
The McKay correspondence can be extended to multiply laced Dynkin diagrams, by using a pair of binary polyhedral groups. This is known as the Slodowy correspondence, named after Peter Slodowy – see.

Labeled graphs

The ADE graphs and the extended ADE graphs can also be characterized in terms of labellings with certain properties, which can be stated in terms of the discrete Laplace operators or Cartan matrices. Proofs in terms of Cartan matrices may be found in.
The affine ADE graphs are the only graphs that admit a positive labeling with the following property:
That is, they are the only positive functions with eigenvalue 1 for the discrete Laplacian – the positive solutions to the homogeneous equation:
Equivalently, the positive functions in the kernel of The resulting numbering is unique up to scale, and if normalized such that the smallest number is 1, consists of small integers – 1 through 6, depending on the graph.
The ordinary ADE graphs are the only graphs that admit a positive labeling with the following property:
In terms of the Laplacian, the positive solutions to the inhomogeneous equation:
The resulting numbering is unique and consists of integers; for E8 they range from 58 to 270, and have been observed as early as.

Other classifications

The elementary catastrophes are also classified by the ADE classification.
The ADE diagrams are exactly the quivers of finite type, via Gabriel's theorem.
There is also a link with generalized quadrangles, as the three non-degenerate GQs with three points on each line correspond to the three exceptional root systems E6, E7 and E8.
The classes A and D correspond degenerate cases where the line set is empty or we have all lines passing through a fixed point, respectively.
There are deep connections between these objects, hinted at by the classification; some of these connections can be understood via string theory and quantum mechanics.
It was suggested that symmetries of small droplet clusters may be subject to an ADE classification.
The minimal models of two-dimensional conformal field theory have an ADE classification.
Four dimensional superconformal gauge quiver theories with unitary gauge groups have an ADE classification.

Trinities

has subsequently proposed many further connections in this vein, under the rubric of "mathematical trinities", and McKay has extended his correspondence along parallel and sometimes overlapping lines. Arnold terms these "trinities" to evoke religion, and suggest that these parallels rely more on faith than on rigorous proof, though some parallels are elaborated. Further trinities have been suggested by other authors. Arnold's trinities begin with R/C/H, which he remarks "everyone knows", and proceeds to imagine the other trinities as "complexifications" and "quaternionifications" of classical mathematics, by analogy with finding symplectic analogs of classic Riemannian geometry, which he had previously proposed in the 1970s. In addition to examples from differential topology, Arnold considers the three Platonic symmetries as corresponding to the reals, complexes, and quaternions, which then connects with McKay's more algebraic correspondences, below.
McKay's correspondences are easier to describe. Firstly, the extended Dynkin diagrams have symmetry groups respectively, and the associated foldings are the diagrams . More significantly, McKay suggests a correspondence between the nodes of the diagram and certain conjugacy classes of the monster group, which is known as McKay's E8 observation; see also monstrous moonshine. McKay further relates the nodes of to conjugacy classes in 2.B, and the nodes of to conjugacy classes in 3.Fi24' – note that these are the three largest sporadic groups, and that the order of the extension corresponds to the symmetries of the diagram.
Turning from large simple groups to small ones, the corresponding Platonic groups have connections with the projective special linear groups PSL, PSL, and PSL, which is deemed a "McKay correspondence". These groups are the only values for p such that PSL acts non-trivially on p points, a fact dating back to Évariste Galois in the 1830s. In fact, the groups decompose as products of sets as: and These groups also are related to various geometries, which dates to Felix Klein in the 1870s; see icosahedral symmetry: related geometries for historical discussion and for more recent exposition. Associated geometries in which the action on p points can be seen are as follows: PSL is the symmetries of the icosahedron with the compound of five tetrahedra as a 5-element set, PSL of the Klein quartic with an embedded Fano plane as a 7-element set, and PSL the with embedded Paley biplane as an 11-element set. Of these, the icosahedron dates to antiquity, the Klein quartic to Klein in the 1870s, and the buckyball surface to Pablo Martin and David Singerman in 2008.
Algebro-geometrically, McKay also associates E6, E7, E8 respectively with: the 27 lines on a cubic surface, the 28 bitangents of a plane quartic curve, and the 120 tritangent planes of a canonic sextic curve of genus 4. The first of these is well-known, while the second is connected as follows: projecting the cubic from any point not on a line yields a double cover of the plane, branched along a quartic curve, with the 27 lines mapping to 27 of the 28 bitangents, and the 28th line is the image of the exceptional curve of the blowup. Note that the fundamental representations of E6, E7, E8 have dimensions 27, 56, and 248, while the number of roots is 27+45 = 72, 56+70 = 126, and 112+128 = 240.
This should also fit into the scheme of relating E8,7,6 with the largest three of the Sporadic simple groups, Monster, Baby and Fischer 24', cf. Monstrous Moonshine.