Long-time coherent quantum behaviour of the D-Wave machine

TL;DR

This paper investigates how the D-Wave quantum computer maintains long-time coherent quantum behavior despite short decoherence times, by modeling qubit interactions with gravonons that enable sustained adiabatic evolution.

Contribution

It introduces a model incorporating gravonons to explain sustained coherence and adiabatic evolution in the D-Wave machine, resolving the decoherence-computation time discrepancy.

Findings

Gravonons help suppress current flips in qubits.

Model explains the 10^8 discrepancy between decoherence and computation times.

Coherent evolution occurs in high-dimensional spacetime, not just Schrödinger's 4D framework.

Abstract

Extensive experiments have demonstrated quantum behaviour in the long-time operation of the D-Wave quantum computer. The decoherence time of a single flux qubit is reported to be on the order of nanoseconds, which is much shorter than the time required to carry out a computation on the timescale of seconds. In our contribution we investigate a model of four qubits with one qubit coupled to a phonon and (optionally) to environmental particles of high density of states, called gravonons. The calculations indicate that when no gravonons are present, the current in the qubit is flipped at some time and adiabatic evolution is discontinued. The time dependent wave functional becomes a non-correctable superposition of many excited states. The results demonstrate the possibility of effectively suppressing the current flip and allowing for continued adiabatic evolution when the entanglement to gravonons is included. This adiabatic evolution is, however, a coherent evolution in high dimensional spacetime and cannot be understood as a solution of Schr\"odinger's time dependent equation in four dimensional spacetime. Compared to Schr\"odinger's time development, the evolution is considerably slowed down, though still adiabatic. The properties of our model reflect correctly the experimentally found behaviour of the D-Wave machine and explain the factor of $10^8$ discrepancy between decoherence time and quantum computation time. The observation and our explanation are in analogy to the $10^8$ discrepancy factor found, when comparing experimental results on adsorbate quantum diffusion rate with predictions of Schr\"odinger's time dependent equation, which can also be resolved in a model with the coupling to gravonons included.