Conformal Interactions Between Matter and Higher‐Spin (Super)Fields

Kuzenko, Sergei M.; Ponds, Michael; Raptakis, Emmanouil S. N.

doi:10.1002/prop.202200157

Cited by 13 publications

(10 citation statements)

References 128 publications

(303 reference statements)

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“…□ k ϕ = 0, k > 1 for the scalar matter corresponds to F (0) = (p 2 ) k ; (b) one can choose different types of matter, e.g. fermion ψ, or, more generally, a mixed-symmetry (spin-)tensor field, see [114] for the discussion of the CHS gravity based on the free fermion (called Type-B) and [115,116] for further extensions; (c) supersymmetric extensions should also be possible and be based on the Clifford-Weyl algebra, see the recent [45,61] for N = 1.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

“…We expect that the approach of this paper provides an efficient way to attack some of the problems of CHS fields that have been around for a while: whether conformal gravity is a consistent truncation of CHS gravity [39][40][41]? ; what are the gravitational backgrounds that admit free CHS fields [39][40][41][42][43][44][45]? ; the structure of (HS) Weyl anomaly and, hence, the problem of quantum consistency of CHS gravity.…”

Section: Conclusion and Discussionmentioning

confidence: 99%

“…The induced action approach should be generalizable to mixed-symmetry and supersymmetric cases. In particular, it has recently been advanced to N = 1 supersymmetric CHS case [45,61] and the quadratic part of the action has been obtained via the induced action technique [61].…”

Section: Tseytlin's Approach: Induced Actionmentioning

confidence: 99%

“…Having such a formulation is important for any extension of gravity and should facilitate the study of these theories in the future, e.g. propagation of CHS fields on gravitational backgrounds [39][40][41][42][43][44][45].…”

Section: Introductionmentioning

confidence: 99%

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Covariant action for conformal higher spin gravity

Basile,

Grigoriev,

Skvortsov

2023

J. Phys. A: Math. Theor.

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Conformal Higher Spin Gravity is a higher spin extension of Weyl gravity and is a family of local higher spin theories, which was put forward by Segal and Tseytlin. We propose a manifestly covariant and coordinate-independent action for these theories. The result is based on an interplay between higher spin symmetries and deformation quantization: a locally equivalent but manifestly background-independent reformulation, known as the parent system, of the off-shell multiplet of conformal higher spin fields (Fradkin--Tseytlin fields) can be interpreted in terms of Fedosov deformation quantization of the underlying cotangent bundle. This brings into the game the invariant quantum trace, induced by the Feigin--Felder--Shoikhet cocycle of Weyl algebra, which extends Segal's action into a gauge invariant and globally well-defined action functional on the space of configurations of the parent system. The same action can be understood within the worldline approach as a correlation function in the topological quantum mechanics on the circle.

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Section: Conclusion and Discussionmentioning

confidence: 99%

Section: Conclusion and Discussionmentioning

confidence: 99%

Section: Tseytlin's Approach: Induced Actionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Covariant action for conformal higher spin gravity

Basile,

Grigoriev,

Skvortsov

2023

J. Phys. A: Math. Theor.

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“…For instance, explicit realisations in terms of free scalar and vector multiplets are known for

J_{\alpha (r) {\dot{\alpha }}(r)}

, in Minkowski, [ 63–69 ] AdS [ 70 ] and conformally‐flat backgrounds. [ 71 ] Higher‐spin supercurrent

J_{\alpha (r) {\dot{\alpha }}(r)}

may also be realised in terms of the on‐shell, gauge‐invariant, chiral field strengths

W_{\alpha (r)}

obeying

\bar{D}_{\dot{\beta }}W_{\alpha (r)} =0

and

D^\beta W_{\beta \alpha (r-1)} =0

. Its realisation is given by [70, 72, 73]:

$$\begin{eqnarray} J_{\alpha (r) {\dot{\alpha }}(r) } =W_{\alpha (r)} \bar{W}_{{\dot{\alpha }}(r)} .

…”

Section: Introductionmentioning

confidence: 99%

Three‐Point Functions of Higher‐Spin Supercurrents in 4D N=1${{\cal N}}=1$ Superconformal Field Theory

Buchbinder

Hutomo

Tartaglino‐Mazzucchelli

2022

Fortschritte der Physik

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We develop a general formalism to study the three‐point correlation functions of conserved higher‐spin supercurrent multiplets Jαfalse(rfalse)α̇false(rfalse)$J_{\alpha (r) \dot{\alpha }(r)}$ in 4D scriptN=1${\cal N}=1$ superconformal theory. All the constraints imposed by scriptN=1${\cal N}=1$ superconformal symmetry on the three‐point function false⟨Jα(r1)trueα̇(r1)Jβ(r2)trueβ̇(r2)Jγ(r3)trueγ̇(r3)false⟩$\langle J_{\alpha (r_1) \dot{\alpha }(r_1)} J_{\beta (r_2) \dot{\beta }(r_2) }J_{\gamma (r_3) \dot{\gamma }(r_3)}\rangle$ are systematically derived for arbitrary r1,r2,r3$r_1, r_2, r_3$, thus reducing the problem mostly to computational and combinatorial. As an illustrative example, we explicitly work out the allowed tensor structures contained in false⟨Jα(r)trueα̇(r)Jβtrueβ̇Jγtrueγ̇false⟩$\langle J_{\alpha (r) \dot{\alpha }(r)} J_{\beta \dot{\beta } } J_{\gamma \dot{\gamma }}\rangle$, where Jαα̇$J_{\alpha \dot{\alpha }}$ is the supercurrent. We find that this three‐point function depends on two independent tensor structures, though the precise form of the correlator depends on whether r is even or odd. The case r=1$r=1$ reproduces the three‐point function of the ordinary supercurrent derived by Osborn. Additionally, we present the most general structure of mixed correlators of the form false⟨LLJα(r)trueα̇(r)false⟩$\langle L L J_{\alpha (r) \dot{\alpha }(r)}\rangle$ and false⟨Jα(r1)trueα̇(r1)Jβ(r2)trueβ̇(r2)Lfalse⟩$\langle J_{\alpha (r_1) \dot{\alpha }(r_1)} J_{\beta (r_2) \dot{\beta }(r_2)} L \rangle$, where L is the flavour current multiplet.

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General light-cone gauge approach to conformal fields and applications to scalar and vector fields

Metsaev

2023

J. High Energ. Phys.

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Totally symmetric arbitrary spin conformal fields propagating in the flat space of even dimension greater than or equal to four are studied. For such fields, we develop a general ordinary-derivative light-cone gauge formalism and obtain restrictions imposed by the conformal algebra symmetries on interaction vertices. We apply our formalism for the detailed study of conformal scalar and vector fields. For such fields, all parity-even cubic interaction vertices are obtained. The cubic vertices obtained are presented in terms of dressing operators and undressed vertices. We show that the undressed vertices of the conformal scalar and vector fields are equal, up to overall factor, to the cubic vertices of massless scalar and vector fields. Various conjectures about interrelations between the cubic vertices for conformal fields in conformal invariant theories and the cubic vertices for massless fields in Poincaré invariant theories are proposed.

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Conformal Interactions Between Matter and Higher‐Spin (Super)Fields

Cited by 13 publications

References 128 publications

Covariant action for conformal higher spin gravity

Covariant action for conformal higher spin gravity

Three‐Point Functions of Higher‐Spin Supercurrents in 4D N=1${{\cal N}}=1$ Superconformal Field Theory

General light-cone gauge approach to conformal fields and applications to scalar and vector fields

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