From Locality and Unitarity to Cosmological Correlators

TL;DR

This paper develops new bootstrap methods based on locality, unitarity, and symmetries to compute cosmological correlators directly, reducing reliance on traditional time-evolution calculations in inflationary models.

Contribution

It introduces the Manifestly Local Test and a partial energy recursion relation to efficiently derive inflationary correlators without soft theorems or extensive integrals.

Findings

Successfully bootstrap scalar inflationary trispectra from graviton exchange

Computed all bispectra to all orders in derivatives for a single scalar

Extended bootstrap methods to multi-field inflation scenarios

Abstract

In the standard approach to deriving inflationary predictions, we evolve a vacuum state in time according to the rules of a given model. Since the only observables are the future values of correlators and not their time evolution, this brings about a large degeneracy: a vast number of different models are mapped to the same minute number of observables. Furthermore, due to the lack of time-translation invariance, even tree-level calculations require an increasing number of nested integrals that quickly become intractable. Here we ask how much of the final observables can be "bootstrapped" directly from locality, unitarity and symmetries. To this end, we introduce two new bootstrap tools to efficiently compute cosmological correlators/wavefunctions. The first is a Manifestly Local Test (MLT) that any $n$-point (wave)function of massless scalars or gravitons must satisfy if it is to arise from a manifestly local theory. When combined with a sub-set of the recently proposed Bootstrap Rules, this allows us to compute explicitly all bispectra to all orders in derivatives for a single scalar. Since we don't invoke soft theorems, this can also be extended to multi-field inflation. The second is a partial energy recursion relation that allows us to compute exchange correlators. Combining a bespoke complex shift of the partial energies with Cauchy's integral theorem and the Cosmological Optical Theorem, we fix exchange correlators up to a boundary term. The latter can be determined up to contact interactions using unitarity and manifest locality. As an illustration, we use these tools to bootstrap scalar inflationary trispectra due to graviton exchange and inflaton self-interactions.