Constraining Gravitational and Cosmological Parameters with Astrophysical Data

TL;DR

This paper uses astrophysical data to constrain fundamental physics models, including modifications to gravity and cosmological parameters, demonstrating the potential of future 21 cm surveys to improve parameter measurements significantly.

Contribution

It develops a framework for torsion in spacetime, explores viable f(R) gravity models, and proposes a robust method for cosmological parameter estimation using 21 cm tomography.

Findings

Gravity Probe B observables can be computed in torsion frameworks.

Viable f(R) models can satisfy solar system constraints via scalar mass or Chameleon effect.

Future 21 cm surveys could improve measurements of spatial curvature and neutrino masses by up to two orders of magnitude.

Abstract

We use astrophysical data to shed light on fundamental physics by constraining parametrized theoretical cosmological and gravitational models. Gravitational parameters are those constants that parametrize possible departures from Einstein's general theory of relativity. We develop a general framework to describe torsion in the spacetime around the Earth, and show that certain observables of the Gravity Probe B experiment can be computed in this framework. We also search for viable theories of gravity where the Ricci scalar R in the Lagrangian is replaced by an arbitrary function f(R). Making use of the equivalence between such theories and scalar-tensor gravity, we find that models can be made consistent with solar system constraints either by giving the scalar a high mass or by exploiting the so-called Chameleon Effect. Cosmology can successfully describe the evolution of our universe using six or more adjustable cosmological parameters. There is growing interest in using 3-dimensional neutral hydrogen mapping with the redshifted 21 cm line as a cosmological probe. We quantify how the precision with which cosmological parameters can be measured depends on a broad range of assumptions. We present an accurate and robust method for measuring cosmological parameters that exploits the fact that the ionization power spectra are rather smooth functions that can be accurately fit by 7 phenomenological parameters. We find that a future square kilometer array optimized for 21 cm tomography could have great potential, improving the sensitivity to spatial curvature and neutrino masses by up to two orders of magnitude, to Delta-Omega_k ~ 0.0002 and Delta-m_nu ~ 0.007 eV, and giving a 4 sigma detection of the spectral index running predicted by the simplest inflation models.