Cosmology Quantized in Cosmic Time

TL;DR

This paper presents a novel quantization approach for cosmological inflation models that incorporates quantum corrections, potentially resolving classical singularities and predicting observable effects on the CMB.

Contribution

It introduces a new quantization method that modifies the Friedmann equation, leading to quantum corrections that impact the universe's evolution and observable cosmological phenomena.

Findings

Quantum corrections eliminate the big crunch problem.

Modified equations suggest measurable effects on CMB radiation.

Application to de Sitter space clarifies the formalism and physical states.

Abstract

This paper discusses the problem of inflation in the context of Friedmann-Robertson-Walker Cosmology. We show how, after a simple change of variables, to quantize the problem in a way which parallels the classical discussion. The result is that two of the Einstein equations arise as exact equations of motion and one of the usual Einstein equations (suitably quantized) survives as a constraint equation to be imposed on the space of physical states. However, the Friedmann equation, which is also a constraint equation and which is the basis of the Wheeler-deWitt equation, acquires a welcome quantum correction that becomes significant for small scale factors. To clarify the general formalism and explicitly show why we choose to weaken the statement of the Wheeler-deWitt equation, we apply the general formalism to de Sitter space. After exactly solving the relevant Heisenberg equations of motion we give a detailed discussion of the subtleties associated with defining physical states and the emergence of the classical theory. This computation provides the striking result that quantum corrections to this long wavelength limit of gravity eliminate the problem of the {\it big crunch}. We also show that the same corrections lead to possibly measurable effects on the CMB radiation. For the sake of completeness, we discuss the special case, $\Lambda=0$, and its relation to Minkowski space. Finally, we suggest interesting ways in which these techniques can be generalized to cast light on the question of chaotic or eternal inflation. In particular, we suggest one can put an experimental lower bound on the distance to a universe with a scale factor very different from our own, by looking at its effects on our CMB radiation.