Non-perturbative wavefunction of the universe in inflation with (resonant) features

Creminelli, Paolo; Renaux-Petel, Sébastien; Tambalo, Giovanni; Yingcharoenrat, Vicharit

doi:10.1007/jhep03(2024)010

Cited by 5 publications

(1 citation statement)

References 29 publications

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“…• Several modifications and improvements of our setup are possible. To name a few, one can consider testing the long-short coupling in the tensor sector [99,100], constructing a UV completion for the mass filter in Model II, and going beyond the Gaussianity constraints (4.40) and (4.41) using non-perturbative techniques [79,101].…”

Section: Jhep05(2024)262mentioning

confidence: 99%

A cosmological tachyon collider: enhancing the long-short scale coupling

McCulloch,

Pajer,

Tong

2024

J. High Energ. Phys.

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The squeezed limit of the primordial curvature bispectrum is an extremely sensitive probe of new physics and encodes information about additional fields active during inflation such as their masses and spins. In the conventional setup, additional fields are stable with a positive mass squared, and hence induce a decreasing signal in the squeezed limit, making a detection challenging.Here we consider a scalar field that is temporarily unstable by virtue of a transient tachyonic mass, and we construct models in which it is embedded consistently within inflation. Assuming IR-finite couplings between the tachyon and the inflaton, we find an exchange bispectrum with an enhanced long-short scale coupling that grows in the squeezed limit parametrically faster than local non-Gaussianity. Our approximately scale-invariant signal can be thought of as a cosmological tachyon collider.In a sizeable region of parameter space, the leading constraint on our signal comes from the cross correlation of μ-type spectral distortions and temperature anisotropies of the microwave background, whereas temperature and polarization bispectra are less sensitive probes. By including anisotropic spectral distortions in the analysis, future experiments such as CMB-S4 will further reduce the allowed parameter space.

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Section: Jhep05(2024)262mentioning

confidence: 99%

A cosmological tachyon collider: enhancing the long-short scale coupling

McCulloch,

Pajer,

Tong

2024

J. High Energ. Phys.

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The open effective field theory of inflation

Salcedo,

Colas,

Pajer

2024

J. High Energ. Phys.

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In our quest to understand the generation of cosmological perturbations, we face two serious obstacles: we do not have direct information about the environment experienced by primordial perturbations during inflation, and our observables are practically limited to correlators of massless fields, heavier fields and derivatives decaying exponentially in the number of e-foldings. The flexible and general framework of open systems has been developed precisely to face similar challenges. Building on previous work, we develop a Schwinger-Keldysh path integral description for an open effective field theory of inflation, describing the possibly dissipative and non-unitary evolution of the Goldstone boson of time translations interacting with an unspecified environment, under the key assumption of locality in space and time. Working in the decoupling limit, we study the linear and interacting theory in de Sitter and derive predictions for the power spectrum and bispectrum that depend on a finite number of effective couplings organised in a derivative expansion. The smoking gun of interactions with the environment is an enhanced but finite bispectrum close to the folded kinematical limit. We demonstrate the generality of our approach by matching our open effective theory to an explicit model. Our construction provides a standard model to simultaneously study phenomenological predictions as well as quantum information aspects of the inflationary dynamics.

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The renormalization group for large-scale structure: primordial non-Gaussianities

Nikolis,

Rubira,

Schmidt

2024

J. Cosmol. Astropart. Phys.

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The renormalization group for large-scale structure (RG-LSS) describes the evolution of galaxy bias and stochastic parameters as a function of the cutoff Λ. In this work, we introduce interaction vertices that describe primordial non-Gaussianity into the Wilson-Polchinski framework, thereby extending the free theory to the interacting case. The presence of these interactions forces us to include new operators and bias coefficients to the bias expansion to ensure closure under renormalization. We recover the previously-derived “scale-dependent bias” contributions, as well as a new (subdominant) stochastic contribution. We derive the renormalization group equations governing the RG-LSS for a large class of interactions which account for vertices at linear order in f NL that parametrize interacting scalar and massive spinning fields during inflation. Solving the RG equations, we show the evolution of the non-Gaussian contributions to galaxy clustering as a function of scale.

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Non-perturbative wavefunction of the universe in inflation with (resonant) features

Cited by 5 publications

References 29 publications

A cosmological tachyon collider: enhancing the long-short scale coupling

A cosmological tachyon collider: enhancing the long-short scale coupling

The open effective field theory of inflation

The renormalization group for large-scale structure: primordial non-Gaussianities

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