Cardy formula for 4d SUSY theories and localization

Pietro, Lorenzo Di; Honda, Masazumi

doi:10.1007/jhep04(2017)055

Cited by 49 publications

(124 citation statements)

References 135 publications

(247 reference statements)

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“…The remaining two terms determine an effective potential for the gauge holonomies and are similar to those first found in [22] (see also [27]). However we have two important differences: the argument of the functions V 1 , V 2 is ρ · u + r 2 instead of ρ · u (because we are taking n 0 = −1 while the setup of [22,27] corresponds to n 0 = 0), and σ, τ are generically complex (while they were assumed purely imaginary in [22,27], which corresponds to real fugacities p = e 2πiσ , q = e 2πiτ ). Recently, similar asymptotic formulae have been discussed in the specific case of N = 4 SYM in [5,6] by allowing for complex values of the fugacities.…”

Section: )supporting

confidence: 60%

“…The first term on the right hand side of (2.14), proportional to the 't Hooft anomaly TrR (see (2.18) below for its definition) and independent of the gauge holonomies, was first obtained in [21]. The remaining two terms determine an effective potential for the gauge holonomies and are similar to those first found in [22] (see also [27]). However we have two important differences: the argument of the functions V 1 , V 2 is ρ · u + r 2 instead of ρ · u (because we are taking n 0 = −1 while the setup of [22,27] corresponds to n 0 = 0), and σ, τ are generically complex (while they were assumed purely imaginary in [22,27], which corresponds to real fugacities p = e 2πiσ , q = e 2πiτ ).…”

Section: )mentioning

confidence: 71%

“…The Cardy-like ("high-temperature") limit of the superconformal index was studied in [21,27] using effective field theory arguments on S 3 × S 1 backgrounds, and in [22] using asymptotic properties of the elliptic gamma functions. 5 Assuming real values of the fugacities and taking the limit of small chemical potentials σ, τ , these works found a universal exponential contribution to the index weighted by the 't Hooft anomaly TrR ∝ (a − c) (this can receive corrections in special instances [22]).…”

Section: The Cardy-like Limit Of the Superconformal Indexmentioning

confidence: 99%

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The asymptotic growth of states of the 4d $$ \mathcal{N}=1 $$ superconformal index

Cabo-Bizet

Cassani

Martelli

et al. 2019

J. High Energ. Phys.

101

159

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We show that the superconformal index of N = 1 superconformal field theories in four dimensions has an asymptotic growth of states which is exponential in the charges. Our analysis holds in a Cardy-like limit of large charges, for which the index is dominated by small values of chemical potentials. In this limit we find the saddle points of the integral that defines the superconformal index using two different methods. One method, valid for finite N , is to first take the Cardy-like limit and then find the saddle points. The other method is to analyze the saddle points at large N and then take the Cardy-like limit. The result of both analyses is that the asymptotic growth of states of the superconformal index exactly agrees with the Bekenstein-Hawking entropy of supersymmetric black holes in the dual AdS 5 theory.where the prefactor F is related to the supersymmetric Casimir energy [16,17], and I is essentially the Hamiltonian index. More precisely, when the R-symmetry Wilson line has 1 The black hole entropy is also reproduced by n0 = +1, and there is a symmetry between these two choices in that all the equations below can be modified appropriately in order to hold for this choice. 2 The chemical potentials ω1, ω2, ϕ are obtained from a limit of the chemical potentials Ω1, Ω2, Φ. We refer to [1] for details. 3 Specifically, the chemical potentials dual to the angular momenta takes the value Ω * 1,2 = 1 and the potential dual to the R-charge takes the value Φ * = 3 2 as β → ∞ [1].

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Section: )supporting

confidence: 60%

Section: )mentioning

confidence: 71%

Section: The Cardy-like Limit Of the Superconformal Indexmentioning

confidence: 99%

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The asymptotic growth of states of the 4d $$ \mathcal{N}=1 $$ superconformal index

Cabo-Bizet

Cassani

Martelli

et al. 2019

J. High Energ. Phys.

101

159

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“…The 1/β S 1 term was studied in [33]; it is fully gauge invariant and supersymmetric. The finite term W (0) 3d roughly corresponds to the supersymmetric partition function of the 3d N = 2 theory on M 3 obtained from the 4d N = 1 theory by dimensional reduction, up to important subtleties that will not affect our discussion-see [61,62,63,41]. Here, we are interested in the order-β S 1 functional in (3.76).…”

Section: The Small-βmentioning

confidence: 99%

’t Hooft anomalies and the holomorphy of supersymmetric partition functions

Closset

Pietro

Kim

2019

J. High Energ. Phys.

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We study the dependence of supersymmetric partition functions on continuous parameters for the flavor symmetry group, G F , for 2d N = (0, 2) and 4d N = 1 supersymmetric quantum field theories. In any diffeomorphism-invariant scheme and in the presence of G F 't Hooft anomalies, the supersymmetric Ward identities imply that the partition function has a non-holomorphic dependence on the flavor parameters. We show this explicitly for the 2d torus partition function, Z T 2 , and for a large class of 4d partition functions on half-BPS four-manifolds, Z M 4in particular, for M 4 = S 3 × S 1 and M 4 = Σ g × T 2 . We propose a new expression for Z M d−1 ×S 1 , which differs from earlier holomorphic results by the introduction of a non-holomorphic "Casimir" pre-factor. The latter is fixed by studying the "high temperature" limit of the partition function. Our proposal agrees with the supersymmetric Ward identities, and with explicit calculations of the absolute value of the partition function using a gauge-invariant zeta-function regularization.

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“…We mainly study supersymmetric index of the SU(N) N = 4 SYM on S 1 × M 3 . We compute an asymptotic behavior of the index in the limit of shrinking S 1 for arbitrary N by using a refinement [24,25] of supersymmetric Cardy formula [26]. Therefore our approach for the superconformal index case (M 3 = S 3 ) is basically the same as the one in [20].…”

Section: Introductionmentioning

confidence: 99%

Quantum black hole entropy from 4d supersymmetric Cardy formula

Honda

2019

Phys. Rev. D

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123

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We study supersymmetric index of 4d SU (N ) N = 4 super Yang-Mills theory on S 1 × M 3 . We compute asymptotic behavior of the index in the limit of shrinking S 1 for arbitrary N by a refinement of supersymmetric Cardy formula. The asymptotic behavior for the superconformal index case (M 3 = S 3 ) at large N agrees with the Bekenstein-Hawking entropy of rotating electrically charged BPS black hole in AdS 5 via a Legendre transformation as recently shown in literature. We also find that the agreement formally persists for finite N if we slightly modify the AdS/CFT dictionary between Newton constant and N . This implies an existence of non-renormalization property of the quantum black hole entropy. We also study the cases with other gauge groups and additional matters, and the orbifold N = 4 super Yang-Mills theory. It turns out that the entropies of all the CFT examples in this paper are given by 2π Q 1 Q 2 + Q 1 Q 3 + Q 2 Q 3 − 2c(J 1 + J 2 ) with charges Q 1,2,3 , angular momenta J 1,2 and central charge c. The results for other M 3 make predictions to the gravity side. * mh974ATdamtp.cam.ac.uk 1 See also [10] for another embedding.

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Cardy formula for 4d SUSY theories and localization

Cited by 49 publications

References 135 publications

The asymptotic growth of states of the 4d $$ \mathcal{N}=1 $$ superconformal index

The asymptotic growth of states of the 4d $$ \mathcal{N}=1 $$ superconformal index

’t Hooft anomalies and the holomorphy of supersymmetric partition functions

Quantum black hole entropy from 4d supersymmetric Cardy formula

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