The superpotential method in cosmological inflation
Abstract
Scalar field cosmological inflation has a first integral relating the Hubble function and the lagrangian of the scalar field(s), which is known under the names of "Hamilton-Jacobi approach" or "superpotential equation". Here we exploit the simplicity of this superpotential equation and use it as an alternative but equivalent cosmological evolution equation during inflation, replacing the Friedman-Robertson-Walker (FRW) equations. It turns out that all inflationary observables can be calculated directly from its solution (the superpotential). Further, the superpotential equation allows for a simple and direct calculation of the slow-roll expansion to arbitrary order and, in many cases, for an exact determination of the slow-roll attractor. It also allows for a power series expansion in the inflaton field which permits to estimate the radius of convergence of the slow-roll expansion. We consider several examples of single-field inflationary models to demonstrate the simplicity and usefulness of the method.
Keywords
Cite
@article{arxiv.1901.02892,
title = {The superpotential method in cosmological inflation},
author = {C. Adam and D. Varela},
journal= {arXiv preprint arXiv:1901.02892},
year = {2019}
}
Comments
Latex file, 38 pages, 11 figures; v3: some further comments on the exact slow-roll attractor solutions and on the (complex-continued) Breitenlohner-Freedman bound added in Section V.B; several references and the pertinent remarks added