On the UV completion of the O(N) model in 6 − ϵ dimensions: a stable large-charge sector

We analyze a recently proposed supersymmetry breaking mass deformation of the E1 superconformal fixed point in five dimensions which, at weak gauge coupling, leads to pure SU(2) Yang-Mills and which was conjectured to lead to an interacting CFT at strong coupling. We provide an explicit geometric construction of the deformation using brane-web techniques and show that for large enough gauge coupling a global symmetry is spontaneously broken and the theory enters a new phase which, at infinite coupling, displays an instability. The Yang-Mills and the symmetry broken phases are separated by a phase transition. Depending on the structure of the potential, this can be first or second order.

Section: Introduction and Summary Of Resultsmentioning

confidence: 99%

Supersymmetry breaking deformations and phase transitions in five dimensions

Bertolini

Mignosa

2021

“…Even-and odddimensional spheres are known to behave differently [43] (the heat kernel trace is convergent in odd dimensions) and it would be interesting to see how this reflects in the resurgence analysis at large charge. Another possibility is to build on the results of a different doublescaling limit, studying the Wilson-Fisher point at large charge in the ε-expansion [26,[50][51][52][53][54][55][56][57][58][59][60]. In the same spirit, it would be interesting to perform a resurgence analysis of supersymmetric systems, both at large R-charge and in the double-scaling limit g → 0, Q → ∞ [18][19][20][21].…”

Section: Discussionmentioning

confidence: 99%

“…where the coefficients f n cannot be computed within the eft: they enter as an input and have to be computed independently, e.g. in a double-scaling limit [26,[49][50][51][52][53][54][55][56][57][58][59][60] or on the lattice [4,5]. In our double-scaling limit, the quantities that we have studied above correspond to the minimal energy configuration for this action.…”

Section: Jhep05(2021)035mentioning

confidence: 99%

Resurgence of the large-charge expansion

Dondi

Kalogerakis

Orlando

et al. 2021

We study the O(2N) model at criticality in three dimensions in the double scaling limit of large N and large charge. We show that the large-charge expansion is an asymptotic series, and we use resurgence techniques to study the non-perturbative corrections and to extend the validity of the eft to any value of the charge. We conjecture the general form of the non-perturbative behavior of the conformal dimensions for any value of N and find very good agreement with previous lattice data.

“…Asĵ is increased, the two solutions get closer and "collide" atĵ 0.052, and then move off to the complex plane forĵ > 0.052. This mechanism is 10 The scaling dimensions of large charge operators in the IR fixed point of the cubic model in d = 6 − were recently studied in [29]. However, that work focuses on the regime j √ fixed, which corresponds to small j .…”

Section: Complex Dimensions In 4 < D <mentioning

confidence: 99%

On the large charge sector in the critical O(N) model at large N

Giombi

Jonah

2021

We study operators in the rank-j totally symmetric representation of O(N) in the critical O(N) model in arbitrary dimension d, in the limit of large N and large charge j with j/N ≡ $$ \hat{j} $$ j ̂ fixed. The scaling dimensions of the operators in this limit may be obtained by a semiclassical saddle point calculation. Using the standard Hubbard-Stratonovich description of the critical O(N) model at large N, we solve the relevant saddle point equation and determine the scaling dimensions as a function of d and $$ \hat{j} $$ j ̂ , finding agreement with all existing results in various limits. In 4 < d < 6, we observe that the scaling dimension of the large charge operators becomes complex above a critical value of the ratio j/N, signaling an instability of the theory in that range of d. Finally, we also derive results for the correlation functions involving two “heavy” and one or two “light” operators. In particular, we determine the form of the “heavy-heavy-light” OPE coefficients as a function of the charges and d.