Physics

OPEN Quantum control using quantum memory

M. Roget, B. Herzog, et al.

This groundbreaking research by Mathieu Roget, Basile Herzog, and Giuseppe Di Molfetta introduces a novel quantum numerical scheme that leverages quantum memory to masterfully control the dynamics of a quantum walker. By embedding the control mechanisms into the initial state, this work opens up exciting potentials for simulating complex physics on quantum devices, particularly in curved manifolds.

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~3 min • Beginner • English

Index

Abstract

We propose a new quantum numerical scheme to control the dynamics of a quantum walker in a two-dimensional space-time grid. More specifically, we show how, introducing a quantum memory for each of the spatial grid, this result can be achieved simply by acting on the initial state of the whole system, and therefore can be exactly controlled once for all. As example we prove analytically how to encode in the initial state any arbitrary walker's mean trajectory and variance. This brings significantly closer the possibility of implementing dynamically interesting physics models on medium term quantum devices, and introduces a new direction in simulating aspects of quantum field theories (QFTs), notably on curved manifold.

Publisher

Scientific Reports

Published On

Dec 07, 2020

Authors

Mathieu Roget, Basile Herzog, Giuseppe Di Molfetta