Higher spin supersymmetry at the cosmological collider: sculpting SUSY rilles in the CMB

Alexander, Stephon; Gates, S. James; Jenks, Leah; Koutrolikos, Konstantinos; McDonough, Evan

doi:10.1007/jhep10(2019)156

Cited by 55 publications

(23 citation statements)

References 109 publications

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“…Its underneath idea is that particles produced in the exponentially expanding spacetime interact with each other and leave characteristic imprints on the correlation functions of curvature fluctuations and tensor fluctuations (primordial gravitational waves). For example, the mass of the mediator is encoded in the scaling/oscillation behavior of correlation functions in the soft limit, its spin is extracted from the angular dependence P S (cos θ) [43], and the couplings are read from the size of non-Gaussianities f N L in the correlation functions. For light fields, signals are usually large [26].…”

Section: Introductionmentioning

confidence: 99%

Probing P and CP violations on the cosmological collider

Liu

Tong

Wang

et al. 2020

J. High Energ. Phys.

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In direct analogy to the 4-body decay of a heavy scalar particle, the 4-point correlation function of primordial fluctuations carries P and CP information. The CP violation appears as a P-odd angular dependence in the imaginary part of the trispectrum in momentum space. We construct a model with axion-like couplings which leads to observably large CP-violating trispectrum for future surveys. Furthermore, we show the importance of on-shell particle production in observing P-and CP-violating signals. It is impossible to observe these signals from local 4-scalar EFT operators that respect dS isometries, and thus any such observation can rule out single-field EFT with sufficiently small slow-roll parameters. This calculation opens a new frontier of studying P and CP at very high energy scales. * Electronic address: taoliu@ust.hk † Electronic address: xtongac@connect.ust.hk ‡ Electronic address: phyw@ust.hk § Electronic address:

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Section: Introductionmentioning

confidence: 99%

Probing P and CP violations on the cosmological collider

Liu

Tong

Wang

et al. 2020

J. High Energ. Phys.

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“…This is the focus of the "cosmological collider physics" program [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17]. For various recent ideas in this direction see, [18][19][20][21][22][23][24][25][26][27][28].…”

Section: Introductionmentioning

confidence: 99%

Cosmological collider physics and the curvaton

Kumar

Sundrum

2020

J. High Energ. Phys.

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Primordial non-Gaussianity signatures of extremely heavy particles are reexamined within a simple alternative to the standard inflationary paradigm, in which the primordial fluctuations and the inflationary spacetime expansion are sourced by two different fields. The curvaton scenario provides an example of this in which the distinct roles are played by the curvaton and the inflaton fields, respectively. We study couplings of the curvaton to heavy particles with masses of order the inflationary Hubble scale, and show that they can lead to non-Gaussian signals orders of magnitude larger than those in standard inflation, consistent with explicit effective field theory control of inflationary dynamics. This brings various motivated particle physics signatures, such as loops of heavy gauge-charged scalars and fermions, within future observational reach. The curvaton paradigm can be viewed as a partial UV completion of effective field theories of only inflationary fluctuations in which large non-Gaussian signals of heavy particles have also been discussed, but in which inflationary dynamics is not explicitly derived.

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“…33) where we have written the coefficient of the scalar functional derivative as ∆ − to emphasize that it is the weight of the late-time bulk field profile. The equation (B.33) can also be derived from a purely boundary perspective by demanding invariance of the generating function under the following Weyl transformation[89] …”

mentioning

confidence: 99%

The Cosmological Bootstrap: Spinning correlators from symmetries and factorization

et al. 2021

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We extend the cosmological bootstrap to correlators involving massless spinning particles, focusing on spin-1 and spin-2. In de Sitter space, these correlators are constrained both by symmetries and by locality. In particular, the de Sitter isometries become conformal symmetries on the future boundary of the spacetime, which are reflected in a set of Ward identities that the boundary correlators must satisfy. We solve these Ward identities by acting with weight-shifting operators on scalar seed solutions. Using this weight-shifting approach, we derive three- and four-point correlators of massless spin-1 and spin-2 fields with conformally coupled scalars. Four-point functions arising from tree-level exchange are singular in particular kinematic configurations, and the coefficients of these singularities satisfy certain factorization properties. We show that in many cases these factorization limits fix the structure of the correlators uniquely, without having to solve the conformal Ward identities. The additional constraint of locality for massless spinning particles manifests itself as current conservation on the boundary. We find that the four-point functions only satisfy current conservation if the s, t, and u-channels are related to each other, leading to nontrivial constraints on the couplings between the conserved currents and other operators in the theory. For spin-1 currents this implies charge conservation, while for spin-2 currents we recover the equivalence principle from a purely boundary perspective. For multiple spin-1 fields, we recover the structure of Yang--Mills theory. Finally, we apply our methods to slow-roll inflation and derive a few phenomenologically relevant scalar-tensor three-point functions.

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Higher spin supersymmetry at the cosmological collider: sculpting SUSY rilles in the CMB

Cited by 55 publications

References 109 publications

Probing P and CP violations on the cosmological collider

Probing P and CP violations on the cosmological collider

Cosmological collider physics and the curvaton

The Cosmological Bootstrap: Spinning correlators from symmetries and factorization

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