Quarter-BPS states in orbifold sigma models with ADE singularities

We study the elliptic genera of two-dimensional orbifold CFTs, where the orbifolding procedure introduces du Val surface singularities on the target space. The N=4\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$ \mathcal{N}=4 $$\end{document} characterdecompositionsoftheellipticgenuscontributionsfromthetwistedsectors at the singularities obey a consistent scaling property, and contain information about the arrangement of exceptional rational curves in the resolution. We also discuss how these twisted sector elliptic genera are related to twining genera and Hodge elliptic genera for sigma models with K3 target space.


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conjugacy class are fully determined by how the corresponding rational curve is positioned in relation to the other rational curves in the resolution. These patterns will be described in section 2.
These twisted sector genera are common to all orbifold CFTs with du Val type singularities, the C 2 /G orbifold being only one example. For this reason, they are very natural quantities to study. Most notably, du Val singularities appear in certain orbifold constructions of sigma models with K3 target space, and the twisted sector contributions from the ADE singular points serve as building blocks for the full elliptic genera of these K3 sigma models. The recent discovery of Mathieu moonshine [6][7][8] showed that the multiplicities of quarter-BPS multiplets in K3 sigma models themselves obey a remarkable numerical property in that they coincide with dimensions of non-trivial representations of the sporadic group M 24 . Since certain K3 geometries can be obtained by orbifolding other K3 geometries, and since the orbifolding procedure introduces du Val singularities, one would expect that the elliptic genus contributions from twisted sectors around du Val singularities, which obey the curious numerical properties described above, should be related to the twined K3 elliptic genera of Mathieu moonshine. This intricate network of relationships, along with other connections to K3 sigma models, is explained in section 3.

The C /G orbifold
Since C 2 is a hyperkähler manifold, there is a natural two-dimensional N = (4,4) superconformal sigma model with C 2 target space. It consists of a pair of free complex bosons parametrising C 2 , and pairs of free left-and right-moving complex fermions taking values in the tangent bundle of C 2 . The central charge is c =c = 6. The natural SU(2) group acting on the coordinates of C 2 preserves the hyperkähler structure, so any orbifold of the sigma model by a subgroup G ⊂ SU (2) inherits the N = (4, 4) superconformal symmetry.
When G is a finite subgroup of SU (2), the space C 2 /G has a du Val surface singularity at the origin, whose preimage in the minimal resolution consists of a collection of rational curves with intersection matrix given by an ADE Dynkin diagram: • The A k singularity: G is the cyclic group of order k + 1.
• The D k singularity: G is the binary dihedral group of order 4k − 8.
• The E 6 singularity: G is the binary tetrahedral group of order 24.
• The E 7 singularity: G is the binary octohedral group of order 48.
• The E 8 singularity: G is the binary icosahedral group of order 120.
Explicit generators for these discrete subgroups are provided in the appendix.
Our quantity of interest is the elliptic genus of the theory. The elliptic genus [9,10] is a partition function defined as the following trace over Ramond-Ramond states:

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Here, F is the fermion number operator, L 0 andL 0 are the left-and right-moving Virasoro generators, and J 0 is a left-moving R-symmetry generator. The elliptic genus contains information about the degeneracies of half-BPS and quarter-BPS multiplets in the theory.
Because the orbifold theory 2 on C 2 /G is obtained from the free theory on C 2 by introducing twisted sectors, and by projecting onto states invariant under G, the elliptic genus for the orbifold can be written as a sum over twisted and twined elliptic genera of the free theory, Z C 2 /G (q,q, y) = 1 |G| g∈G h∈G Z C 2 ,(g,h) (q,q, y), where Z C 2 ,(g,h) (q,q, y) := Tr g−twisted,RR h(−1) F q L 0qL0 y J 0 .
The untwisted sector contribution to Z C 2 /G (i.e. the contribution with g equal to the identity element) includes a sum over a continuous spectrum of scattering states. While there are ways of regularising this sum (see [14] for example), this untwisted sector is not the main focus of this article, and will play no further part in our discussion.
We will instead focus on the contribution to Z C 2 /G (q,q, y) from the twisted sectors, which is a well-defined sum over a discrete spectrum of states. In the second half of this article, we will explain how the quantity Z C 2 /G,twisted can be viewed as a universal quantity valid for any orbifold sigma model where the orbifolding introduces a du Val singularity of the same ADE type. As already mentioned, the elliptic genus encodes information about the half-BPS and quarter-BPS spectrum of the sigma model. The multiplets of the N = 4 superconformal algebra at central charge c = 6 are as follows: • A short multiplet whose highest weight state has eigenvalues (L 0 , J 0 ) = (h, j) = ( 1 4 , 0). This multiplet has Witten index 1.
From the perspective of the right-movers, the elliptic genus is merely a Witten index. So the elliptic genus only receives contributions from short multiplets in the right-moving sector. In particular, it is independent ofq, at least in the twisted sectors (where there JHEP06(2017)116 are no issues with regularisation), which explains why theq variable is dropped from our notation. However, the elliptic genus receives contributions from both short and long multiplets in the left-moving sector. Defining the character of the left-moving N = 4 multiplet with highest weight (h, j) as one can decompose the twisted sector contribution to the elliptic genus of C 2 /G as a linear combination of these characters, Explicit expressions for the characters ch h,j (q, y) have been computed in [15,16], and are reproduced in the appendix for convenience.
The full spectrum of twisted sector states decomposes into a direct sum of tensor products of left-moving and right-moving N = 4 multiplets, where the integer c (h,j),(h,j) denotes the multiplicity with which the tensor product of the left-moving (h, j)-multiplet and the right-moving (h,j)-multiplet appears in the twisted sector spectrum.
Each coefficient a (h,j) can then be interpreted as the sum of the Witten indices 3 of all right-moving short multiplets paired with the left-moving (h, j)-multiplet in the twisted sector spectrum: Thus the a (h,j) coefficients can be viewed as signed counts of half-BPS (short-short) multiplets and quarter-BPS (long-short) multiplets in the twisted sectors.
The elliptic genus and the character decompositions can computed by standard techniques, as described in the appendix. Here, we proceed directly to the results, beginning with the A k type singularities: is the Witten index contribution from the twisted sectors, which is equal to the number of exceptional rational curves in the minimal resolution of the A k singularity, consistent with the expectation that the Witten index contribution from the twisted sectors should be the difference between the Euler characteristics of the resolved and unresolved geometries. 4 Moreover, the Witten index of the twisted sector is also equal to the number of non-identity conjugacy classes in G (see the appendix for details). This correspondence between conjugacy classes in G and exceptional rational curves is a manifestation of the McKay correspondence [1][2][3].
Our main interest in this article, however, is in the coefficients a 1 4 +n, 1 2 for n ≥ 1, which provide signed counts of the quarter-BPS multiplets in the twisted sectors. A pattern emerges when we compute the differences between the signed quarter-BPS counts between successive values of k: 4 Since the resolution of an ADE singularity is a continuous deformation of the CFT [11,12], the full Witten index of the theory is equal to the Euler characteristic of the resolved geometry. Meanwhile, the Witten index of the untwisted sector, computed from G-invariant states on the space before quotienting, is the Euler characteristic of the unresolved quotient space. The Witten index of the twisted sectors is their difference. Of course, this description is problematic for C 2 /G because of the continuous spectrum of untwisted sector states, which needs to be regularised; however, the same argument applies for the compact geometries that we shall consider in section 3, where there are no issues with regularisation. The fact that the Witten index contributions come from a 1 4 ,0 rather than from a The signed counts of sufficiently low-lying quarter-BPS multiplets increase by a constant increment every time the number of nodes k in the A k Dynkin diagram increases.
To be more precise, the increment in a 1 4 +n, 1 2 from A k to A k+1 stabilises when k ≥ n.
(The low-lying multiplets to which this pattern applies are highlighted for emphasis.) The regular increment is given by the sequence:  The increments stabilise to the same sequence as for the A k series. However, the rate at which stabilisation occurs is twice as fast for the D k series as for the A k series: the increment in a 1 4 +n, 1 2 from D k to D k+1 stabilises when 2k − 5 ≥ n. Finally, we turn to the E k singularities:  The differences between successive E k singularities are shown below, and can be seen to stabilise to the same sequence as before, and the stabilisation happens twice as fast as compared to the A k series. In some sense, these patterns can be viewed as a quarter-BPS generalisation of the stringy McKay correspondence. It is intuitive that the multiplicities of quarter-BPS multiplets should increase every time an additional P 1 is added to the exceptional divisor, as is the case for half-BPS multiplets -but why the regular increment only applies to multiplets with sufficiently low conformal dimension relative to the number of exceptional P 1 's, and why the growth is governed by this particular sequence of numbers, is mysterious.
So far, we have only presented the character decompositions summed over all twisted sectors for all non-identity elements in G. It is possible to split these character decompositions further into contributions from twisted sectors for individual conjugacy classes in G. For any given conjugacy class, the sum over contributions from sectors twisted by group elements within the chosen conjugacy class does indeed admit an integer-valued character decomposition. Furthermore, each conjugacy class can be associated in a natural way to a node in the Dynkin diagram, and it can be verified that the contribution from a given conjugacy class only depends, in a certain sense, on the environment that its associated node occupies within the Dynkin diagram. (Details are again provided in the appendix.)

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• For an A k singularity, the character contribution from the node in the p th position from the left is equal to the contribution from the node in the p th position from the right. (If k is odd, with k = 2l + 1, then one may view the diagram as a central node with two tails of length l attached; this facilitates comparison with the D and E type singularities.) Moving from the central node(s) to the outer nodes, the a 1 4 +n, 1 2 coefficients always increase monotonically.
• The Dynkin diagram for a D k singularity consists of a central node, attached to three tails of length 1, 1 and k − 3 respectively. The Dynkin diagram for an E k singularity consists of a central node, attached to three tails of length 1, 2 and k − 4. For any D k or E k singularity, the character contribution from a node situated on a tail of length l in the p th position from the end of the tail is equal to the character contribution in the A 2l+1 singularity from a node situated in the p th position from either end of the A 2l+1 diagram. The contributions from the central nodes in the D k and E k diagrams are however distinct from contributions from nodes in A type diagrams. Moving from the central node towards the outer-most node along any given branch in a D or E type diagram, the a 1 4 +n, 1 2 coefficients always increase monotonically.
(In the appendix, we illustrate these patterns in detail for the A 3 and D 4 examples.) Elliptic genera, unlike Euler characteristics, do not obey an inclusion-exclusion principle, 5 so it is rather surprising that there is a natural way to associate elliptic genus contributions from individual conjugacy classes to particular irreducible blow-up divisors, and that these contributions appear to carry information about how the associated irreducible divisors are positioned with respect to the other irreducible divisors.

ADE singularities in other orbifolds
Although we have focused on the C 2 /G orbifold in our discussion so far, the quantities we have studied are also relevant to general orbifolds with singularities of ADE type. Our Z C 2 /G,twisted quantities can therefore be viewed as a generic set of building blocks for the elliptic genera of all orbifold CFTs where the orbifolding procedure introduces ADE type singularities. Indeed, this was the author's original motivation for studying these quantities. In this section, we will develop the story in this more general setting, and we will explain how our Z C 2 /G,twisted quantities, whose numerical properties were studied in the previous section, are related to indices associated to sigma models with compact target space.
Let us therefore consider a two-dimensional N = (4, 4) sigma model with target space M , where M is now a general smooth hyperkähler manifold of complex dimension two. Suppose that M has an isometry G that preserves the hyperkähler structure, and suppose that the action of every non-identity element in G has only isolated fixed points on M ,

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which descend to ADE type singularities under the quotienting projection M → M/G. Then the elliptic genus of the M/G orbifold theory is where the untwisted sector contribution Z G M (q,q, y) is the index computed from G-invariant states on M , and Sing(M/G) denotes the singular locus of M/G.
Of course, the untwisted sector contribution Z G M depends considerably on the global structure of the hyperkähler manifold M . However, each twisted sector contribution Z x,twisted only depends on the ADE classification of the singularity at x. Therefore, each Z x,twisted is identical to the Z C 2 /G,twisted of corresponding ADE type. In this way, our Z C 2 /G,twisted quantities are universal properties of ADE orbifolds.
(This conclusion follows, for instance, from the general orbifold formula for elliptic genera in [20][21][22][23], where the twisted sector contributions for isolated x ∈ Sing(M/G) are given solely in terms of the eigenvalues of the action of elements of Stab(x) ⊂ G on the tangent space T x M . The qualitative difference between the untwisted and twisted sectors relies crucially on the fact that the identity element in G fixes the whole of M , whereas the non-identity elements in G have isolated fixed points.) Now, consider the case where M is compact, which implies that M is either a torus T 4 = C 2 /Λ or a K3 surface, and take G to be a finite group of symplectic automorphisms, acting on M with isolated fixed points that descend to du Val singularities on M/G. Then the minimal resolution M/G is a smooth K3 surface. 6 These orbifold K3 sigma models occur at very special points in the K3 moduli space. Such points in moduli space are characterised by the fact that the classes in H 2 (K3) with self-intersection −2 that correspond to the exceptional rational curves are orthogonal to the generator Ω of H 2,0 (K3) and also to the Kähler form ω in H 1,1 (K3); 7 in particular, the Picard rank of the K3 is at least as large as the number of exceptional rational curves in the minimal resolution. (However, the exceptional (−2)-cycles carry non-trivial B-field flux [30,31].) 8 These orbifold sigma models have marginal operators generating deforma-6 A symplectic automorphism g ∈ Aut(M ) is one that fixes the generator Ω ∈ H 2,0 (M ). Given a finite group of symplectic automorphisms G, one can always find a Kähler form that is invariant under the action of G: indeed, if ω ∈ H 1,1 (M ) is any Kähler form, then the group average 1 |G| g∈G g ⋆ ω is invariant under the action of G. Since a symplectic automorphism fixes the global non-vanishing holomorphic two-form Ω, the canonical bundle is trivial on the open set of smooth points in M/G, and since minimal resolutions of ADE singularities are crepant resolutions, M/G also has a trivial canonical bundle; see [24] for example. 7 The position in moduli space is uniquely specified by how the real four-plane spanned by Re Ω, Im Ω, Re exp(B + iω) and Im exp(B + iω) embeds into H ⋆ (K3) ⊗ R modulo lattice automorphisms (where the lattice H ⋆ (K3) is endowed with the Mukai intersection form) [25][26][27] (see also [28,29]). This is a physical version of the global Torelli theorem. 8 In fact, there is no reason to expect that every K3 sigma model with ADE type singularities in the target space can be realised as an orbifold of T 4 , or of another K3 surface. Nonetheless, even in these cases, the singularities will locally be indistinguishable from the singularities that arise from orbifolding, provided that the B-field fluxes through the ADE rational curves are tuned to match the values obtained by the orbifolding procedure. Therefore, it is reasonable to believe that these sigma models will also contain sectors of states that wind around the singularities whose elliptic genus contributions are identical to the contributions from twisted sectors in orbifolds given by the Z C 2 /G,twisted functions.

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tions equivalent to resolving the singularities [11,12], which can be viewed as deforming the Kähler form ω so that it is no longer orthogonal to the exceptional curves.
Since elliptic genera on compact spaces are always invariant under continuous deformations [9], the elliptic genus of the orbifold, Z M/G (q, y), is equal to the elliptic genus of the minimal resolution, Z M/G (q, y) (see also [22] for a mathematical proof). Meanwhile, the quantity Z G M (q, y) can be decomposed as a group average of twined elliptic genera Z g M (q, y) for the manifold M , For any compact complex manifold X with trivial canonical bundle, the elliptic genus, and more generally, the twined elliptic genera, can be defined geometrically as follows [32,33]: if g ∈ Aut(X) is an automorphism fixing the generator of H dim C (X),0 (X), then the twined elliptic genus Z g X (q, y) is given by a signed character for the action of g ⋆ on the sheaf cohomology groups of E q,y , where E q,y is the formal power series of vector bundles, When g is taken to be the identity automorphism, this reduces to the standard elliptic genus Z X (q, y) of X. By considering the Chern roots of T X , it can be shown that Z X (q, y) is a weak Jacobi form of weight zero and index dim C (X)/2 [32]; in particular, it is independent of theq variable. Other twining genera obey similar modularity properties for congruence subgroups. The N = 4 character decomposition of Z X (q, y) may then be interpreted as the coefficients of a mock modular form associated to the weak Jacobi form Z X (q, y) [34]. If M is chosen to be a K3 surface, then we are in a situation where both M and M/G are K3 surfaces. Because the moduli space of K3 sigma models is connected and the elliptic genus is invariant under continuous deformations, all K3 sigma models have the same elliptic genus. Furthermore, finite-order symplectic automorphisms of K3 surfaces have been classified [35,36]: they all give rise to ADE type singularities under quotienting, and the number of fixed points, as well as the eigenvalues of the action of the automorphisms on the tangent spaces at the fixed points, are uniquely determined by the orders of the automorphisms in the group G. For any g other than the identity element, the fixed points of g are isolated, so the traces tr g ⋆ | H i (Eq,y) in the definition of Z g X (q, y) can be written down directly in terms of the eigenvalues of the action of g on the tangent spaces at the fixed points using the holomorphic Lefschetz fixed point formula [37]. Therefore, the twining genera are also uniquely determined by the order of the group element g.
The character decompositions of Z g K3 have been computed in [7,8], and are tabulated below. The numbers in the left-hand column denote the order of the relevant automor- Thus, in the case where M is a K3 surface, the relationship leads to a collection of relationships between the Mathieu twining genera and the quantities Z C 2 /G,twisted whose properties were described in the previous section.
For instance, suppose G is generated by a single symplectic automorphism of order 2. By the classification in [35] (see also table 1 in [33] where these results are collected), M/G has eight A 1 singularities. Thus we obtain the relationship, This relationship can be verified from the a h,j coefficients that we computed earlier for the A 1 singularity. For higher order automorphisms, one obtains similar relationships involving Z A k ,twisted for k ∈ {1, 2, . . . , 7}, which can be verified in the same way, and which enable 9 Mathieu moonshine states that for each n, there exists a non-trivial M24 representation such that for each g, the coefficient a g
There are also examples of K3 surfaces whose groups of finite-order symplectic automorphisms are generated by more than one element. Their quotients contain combinations of du Val singularities of type A 1 , . . . , A 7 , D 4 , D 5 , D 6 and E 6 . There are eighty-one cases altogether, and they are classified in [24]. Each such example leads to a relationship between the respective Mathieu twining functions and the appropriate Z C 2 /G,twisted in the same way as before. To give just one example, the thirty-seventh case listed in [24] is a K3 surface with a sympletic automorphism group isomorphic to the binary tetrahedral group (a group with one element of order 1, one element of order 2, eight elements each of orders 3 and 6, and six elements of order 4), and the quotient M/G contains two A 2 singularities, plus singularites of type A 5 , D 4 and E 6 . This leads to the relationship, Of course, the logic can be turned the other way round: the requirement for the existence of a relationship of this form provides a simple, non-trivial, consistency check for the existence of an M with a symplectic automorphism group G with given fixed point structure.
Instead of taking M to be a K3 surface, one could also take M to be a torus T 4 = C 2 /Λ. As before, G is a non-trivial group of discrete symplectic automorphisms with isolated fixed points. The resolved quotient M/G is again a K3 surface. These complex tori have been classified in [30]: there are eight cases, giving rise to various combinations of A 1 , . . . A 5 , D 4 , D 5 and E 6 singularities in the quotient M/G. Again, one obtains relationships between twining genera and the twisted sector contributions from the singularities. For instance, the simplest case is where G is the order two group generated by the Kummer involution ι sending (x, y) ∈ C 2 /Λ to (−x, −y). Since the quotient M/G has sixteen A 1 singularities, we obtain the relationship, However, T 4 has trivial tangent bundle, and since the holomorphic Euler characteristic of a trivial bundle on T 4 is zero by Hirzebruch-Riemann-Roch, we have Z T 4 = 0. Furthermore,

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the Kummer involution ι has sixteen isolated fixed points whereas an order two symplectic automorphism of a K3 surface only has eight isolated fixed points [33,35], so by the holomorphic Lefschetz fixed point formula, Z ι T 4 = 2Z 2A K3 . Thus the relationship reduces to Z K3 = Z 2A K3 + 16Z A 1 ,twisted , which is a rearrangement of a relationship that we have already found. Similar relationships can be obtained for the other seven cases of T 4 /G classified in [30].
The decomposition of Z M/G into a contribution from G-invariant quarter-BPS multiplets on M plus contributions from ADE twisted sectors is useful for making sense of a puzzle in [17,18], for certain special cases. In [17,18], the authors study the unsigned counts of quarter-BPS multiplets in K3 sigma models. In a generic K3 sigma model, the multiplicities of quarter-BPS multiplets are simply given by c 2 ) ), and the puzzle is to characterise these jumping loci in the moduli space of K3 sigma models. On the special loci in moduli space where the K3 sigma model is an orbifold of the form T 4 /G, we can describe qualitatively how the enhancement of the quarter-BPS spectrum occurs. First, we have contributions from each ADE twisted sector, which, as described in the previous section, are approximately proportional to the number of nodes in the corresponding ADE Dynkin diagram; by a simple free field calculation of a refined index called the Hodge elliptic index (defined in [17]), which essentially reduces to observing that the twisted sectors have no right-moving fermion zero modes, these twisted sector contributions to the quarter-BPS spectrum can be seen to give no enhancement to the quarter-BPS spectrum. Therefore, all of the enhancements to the quarter-BPS spectrum on T 4 /G come from G-invariant enhancements to the quarter-BPS spectrum on T 4 , which, as described in [18], depend on the Kähler and complex structure of the T 4 , and are particularly large at special points in the moduli space (for instance at points where the T 4 is isomorphic to a product of two elliptic curves with complex multiplication and where the Kähler structure obeys an analogous condition). An immediate consequence of this description is that, if G is a hyperkähler-preserving automorphism group of a particular T 4 , and H is a subgroup of G, then the enhancements in the quarter-BPS spectrum of T 4 /H are larger than the enhancements in the quarter-BPS spectrum of T 4 /G.

Concluding remarks
The most immediate question arising from our discussion is whether the sequence, 4, 20, 66, 194, 492, 1178, 2606, 5530, . . . which controls the growth of the ADE twisted sector character decompositions, has a natural origin. For example, one might speculate that the repetition of this sequence is a sign that sufficiently low-lying quarter-BPS multiplets experience some enhanced symmetry JHEP06(2017)116 algebra. Alternatively, the fact that the multiplicities approach a stable pattern could also be a subtle consequence of modular invariance.
One might also wish to investigate whether the apparent correspondence between conjugacy classes and irreducible blow-up divisors can be formulated as a more general statement for higher-dimensional target spaces in such a way that the quarter-BPS spectra from twisted sectors for individual conjugacy classes encode positional information about their associated divisors. If so, it would then be natural to investigate the fate of the quarter-BPS states under the blow-up deformation; for instance, one might conjecture that the quarter-BPS states associated to a given conjugacy class deform continuously into states localised around their associated irreducible divisor in the resolution.
Finally, it would be interesting to further explore the relationship between the ADE twisted sector character decompositions and twining genera. Indeed, there are twenty-three cases of umbral moonshine, of which M 24 is only one instance, and these twenty-three cases of umbral moonshine admit an ADE classification of their own [38,39].

Acknowledgments
The author would like to thank Nathan Benjamin, Arnav Tripathy, Roberto Volpato, Milind Shyani, Shamit Kachru and David Tong for stimulating discussions. The author is supported by Gonville and Caius College and the ERC Grant agreement STG 279943.

A Computations and formulae
Computation of elliptic genera. Here, we provide expressions for the twisted sector contributions to the elliptic genus on C 2 /G, First of all, note that a group element h sends the vacuum state in the twisted sector associated to the group element g to the vacuum state in the twisted sector associated to the group element hgh −1 . Therefore, for a given g ∈ G\{e}, we only need to sum over contributions from h in the centraliser of g.
Next, we denote the eigenvalues for the action of a group element g ∈ G on the coordinates of C 2 by α(g) = e 2πiλ(g) and α(g) −1 = e −2πiλ(g) . For h in the centraliser of g, the action of h on the coordinates C 2 can be diagonlised simultaneously with the action of g, and we denote the eigenvalues for the action of h with respect to the same basis by α(h) = e 2πiλ(h) and α(h) −1 = e −2πiλ(h) . The contribution Z C 2 ,(g,h) (q, y) is then given by This formula follows immediately from the geometric formula for the elliptic genus of orbifolds, Equation 1.5 in [20], in which the contributions from the twisted sector for JHEP06(2017)116 a group element whose fixed points are isolated are written in a way that only depends on the eigenvalues of the action of the group element on the tangent spaces at those fixed points. In [20,22], it is shown that this formula obeys key consistency conditions, including modularity properties, the DMVV formula for symmetric products [40], and invariance under crepant resolution of singularities. The formula in [20] is valid for (but not restricted to) general orbifolds with du Val singularities, so our results apply not just to C 2 /G, but also for arbitrary orbifolds with ADE singularities.
In the case of C 2 /G, the numerator of the formula can be recognised as a sum over fermionic oscillators, and the denominator can be recognised as a sum over bosonic oscillators (written as summed geometric series). A version of the elliptic genus for A k type singularities has previously been obtained in this form from a localisation computation [14]; there, the formula includes the untwisted sector, regularised by introducing additional chemical potentials.
Discrete subgroups of SU (2). We now provide details of the discrete groups G ⊂ SU(2) used to construct the orbifolds C 2 /G, paying particular attention to the centralisers of the group elements and the eigenvalues e 2πiλ(g) and e 2πiλ(h) . See [12,41] for further details.
For m ≥ 2, the A m−1 singularity is obtained by taking G to be the cyclic group of order m, generated by the element Of course, for any element g = a k with k ∈ {1, . . . , m − 1}, we have λ(g) = k m , and since the centraliser C(g) is the full group, the list of λ(h) for h ∈ C(g) contains one copy of p m for each p ∈ Z m .
For m ≥ 2, the D m+2 singularity is obtained by taking G to be the binary dihedral group of order 4m, generated by the two elements, The full group is {1, a, . . . , a 2m−1 , b, ab, . . . , a 2m−1 b}, and the group elements obey the relation a m = b 2 = −1.
• The element g = −1 has λ(g) = 1 2 . The centraliser C(g) is the entire group, and the list of λ(h) for h ∈ C(g) contains one copy of p 2m for each p ∈ Z 2m , plus a further 2m copies of 1 4 .
• For any k ∈ Z 2m \{0, m}, the element g = a k has λ(g) = k 2m . The centraliser C(g) contains all elements of the form a p , and so the list of λ(h) for h ∈ C(g) contains one copy of p 2m for each p ∈ Z 2m .

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• For any k ∈ Z 2m , the element g = a k b has λ(g) = 1 4 . We have C(g) = {1, a m , a k b, a m+k b}, and the list of λ(h) for h ∈ C(g) contains one copy of p 4 for each p ∈ Z 4 . Now let x, y, z be the quaternion generators, The E 6 singularity arises when G is the binary tetrahedral group. The elements of this order 24 group are the eight quaternions {±1, ±x, ±y, ±z}, combined with sixteen elements of the form 1 2 (±1 ± x ± y ± z).
• The element g = −1 has λ(g) = 1 2 . It commutes with the entire group, and the list of λ(h) for h ∈ C(g) contains one copy of 0, one copy of 1 2 , six copies of 1 4 , eight copies of 1 6 and eight copies of 1 3 .
• There are six elements g of order four with λ(g) = 1 4 . For each such element, the list of λ(h) for h ∈ C(g) contains one copy of p 4 for each p ∈ Z 4 .
• There are eight elements g of order six with λ(g) = 1 6 , and a further eight elements g of order three with λ(g) = 1 3 . For any of these elements, the list of λ(h) for h ∈ C(g) contains one copy of p 6 for each p ∈ Z 6 . The E 7 singularity arises when G is the binary octohedral group. This order 48 group contains the quaternions {±1, ±x, ±y, ±z}, all elements of the form 1 2 (±1 ± x ± y ± z), and all elements obtained from 1 √ 2 (±1 ± x) or 1 √ 2 (±y ± z) by permuting the set {x, y, z}.
• The element g = −1 has λ(g) = 1 2 . It commutes with the entire group, and the list of λ(h) for h ∈ C(g) contains one copy of 0, one copy of 1 2 , eighteen copies of 1 4 , eight copies each of 1 3 and 1 6 and six copies each of 1 8 and 3 8 .
• There are twelve elements of order four with λ(g) = 1 4 , for which the list of λ(h) for h ∈ C(g) contains one copy of p 4 for each p ∈ Z 4 .
• There are eight elements of order six with λ(g) = 1 6 and a further eight elements of order three with λ(g) = 1 3 . For any of these elements, the list of λ(h) for h ∈ C(g) contains one copy of p 6 for each p ∈ Z 6 .
• There are six elements of g order eight with λ(g) = 1 8 , plus a further six elements g of order four with λ(g) = 1 4 , plus six elements of order eight with λ(g) = 3 8 . For any of these elements, the list of λ(h) for h ∈ C(g) contains one copy of p 8 for each p ∈ Z 8 .

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does not require explicit computation to verify; it follows immediately from coincidences between the eigenvalues λ(g), and λ(h) for h ∈ C(g), for the various discrete subgroups G. For instance, consider the cyclic group of order four, which corresponds to the A 3 singularity. This has three non-identity conjugacy classes: {a}, {a 2 } and {a 3 }. One may associate these conjugacy classes with the three nodes on the A 3 Dynkin diagram, in that order. From their eigenvalues, it is clear that the contributions from the twisted sector for a and the contribution from the twisted sector for a 3 (i.e. the twisted sectors associated to the two outer nodes on the Dynkin diagram) are equal to one another, but are distinct from the contribution from the twisted sector for a 2 (i.e the twisted sector associated to the central node on the Dynkin diagram). For concreteness, we tabulate the individual contributions below:

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This contribution is the contribution associated to a node situated in the p th position from either end of the chain in the A k diagram, and if k is odd, this is also the contribution from a node situated in the p th position from the end of any tail of length 1 2 (k − 1) in a D or E type diagram. By explicit computation, one observes that the growth of a 1 4 +n, 1 2 ,Cl({a p }) , as k increases, eventually stabilises. In the table below, we give expressions for these character contributions, for k sufficiently large that the growth has stabilised. We also give the corresponding expressions for the central node in the D k diagrams.   Remarkably, the growth pattern for the entire Dynkin diagram (described in the main text) always stabilises at a lower value of k than the growth patterns for the individual nodes -though of course, these growth patterns are consistent with one another.
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