Abstract
Developing our understanding of how correlations evolve during inflation is crucial if we are to extract information about the early Universe from our late-time observables. To that end, we revisit the time evolution of scalar field correlators on de Sitter spacetime in the Schrödinger picture. By direct manipulation of the Schrödinger equation, we write down simple “equations of motion” for the coefficients which determine the wavefunction. Rather than specify a particular interaction Hamiltonian, we assume only very basic properties (unitarity, de Sitter invariance and locality) to derive general consequences for the wavefunction’s evolution. In particular, we identify a number of “constants of motion” — properties of the initial state which are conserved by any unitary dynamics — and show how this can be used to partially fix the cubic and quartic wavefunction coefficients at weak coupling. We further constrain the time evolution by deriving constraints from the de Sitter isometries and show that these reduce to the familiar conformal Ward identities at late times. Finally, we show how the evolution of a state from the conformal boundary into the bulk can be described via a number of “transfer functions” which are analytic outside the horizon for any local interaction. These objects exhibit divergences for particular values of the scalar mass, and we show how such divergences can be removed by a renormalisation of the boundary wavefunction — this is equivalent to performing a “Boundary Operator Expansion” which expresses the bulk operators in terms of regulated boundary operators. Altogether, this improved understanding of the wavefunction in the bulk of de Sitter complements recent advances from a purely boundary perspective, and reveals new structure in cosmological correlators.
Highlights
Model-independent approach to studying cosmological correlators is very much inspired by the successes enjoyed by the S-matrix programme on flat Minkowski space [1, 2], in which similar foundational properties can be used to efficiently bootstrap scattering amplitudes without specifying a particular Lagrangian
These objects exhibit divergences for particular values of the scalar mass, and we show how such divergences can be removed by a renormalisation of the boundary wavefunction — this is equivalent to performing a “Boundary Operator Expansion” which expresses the bulk operators in terms of regulated boundary operators
At the simplest level, inflationary correlators may be approximated by the correlators of a scalar field on a fixed de Sitter spacetime — this is the focus of our work
Summary
Model-independent approach to studying cosmological correlators is very much inspired by the successes enjoyed by the S-matrix programme on flat Minkowski space [1, 2], in which similar foundational properties (unitarity, Lorentz invariance and locality) can be used to efficiently bootstrap scattering amplitudes without specifying a particular Lagrangian (see e.g. [3,4,5] for recent reviews). Modern computations of the wavefunction often favour path integral techniques [17,18,19] (e.g. borrowing the bulk-to-boundary and bulk-to-bulk propagators of holography to compute the on-shell action), in this work we adopt the Schrödinger picture, representing observables in terms of φand its canonical momentum Π , and Ψη[φ] is determined by solving the Schrödinger equation. This picture naturally focuses on the interaction Hamiltonian rather than the Lagrangian, and so properties such as unitarity (hermiticity of the Hamiltonian) are made manifest.. Since Ψη[φ] is a functional, unitarity leads to the conservation of an infinite number of functions (one at each order in φn) — we will call these constants of motion {βn}, and here we construct the first two explicitly at weak coupling (neglecting loops)
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