Testing Models of 'Gravity' Using a Quantum Computer

TL;DR

This paper explores quantum models that mimic gravitational phenomena using entanglement and wave functions, proposing new insights into gravity, dark energy, and negative mass within quantum computing frameworks.

Contribution

It introduces quantum models that simulate gravitational effects and dark energy, offering novel perspectives on gravity's nature through quantum information transfer.

Findings

Quantum models can produce fields similar to gravity and dark energy.

Negative gravitational mass can be locally simulated with field cancellation.

The models provide fundamental insights into gravity beyond mere analogy.

Abstract

This article begins by putting forth a model that shows how the storage and retrieval of information on a wave function that involves quantum entanglement behaves similarly to the concepts of length contraction and time dilation, respectively. An exploration is then made to see if another model can be generated based on the one previously mentioned that guides the time evolution of a quantum system in a manner similar to that of gravity. The answer is made in the affirmative, after testing a series of models, by producing a field that is mediated solely by the transfer of quantum information using both quantum entanglement and wave function collapse. While it is readily acknowledged that the effective field produced may not be gravity, the study provides arguments about why the concepts presented do in fact provide fundamental insights about the true nature of gravity as opposed to merely generating similar behavior to gravity. The study moves on to study how a system with uniform effective potential behaves similarly to dark energy, albeit with a system whose construction is severely limited by computational resources. Finally, an exploration is made as to whether a negative gravitational mass can be produced. It is found that while an isolated particle with negative gravitational mass proves to be problematic according to this model, it seems as though a local region with negative gravitational mass can be produced as long as the resulting fields are cancelled out at larger distances.