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FP6

AIQT Résumé de rapport

Project ID: 46432
Financé au titre de: FP6-MOBILITY
Pays: United Kingdom

Final Activity Report Summary - AIQT (Architectures for ion quantum technology)

Quantum mechanics will enable powerful applications due to the emergence of new quantum technologies such as the quantum computer. While such a device will likely provide ground-breaking commercial and national security applications due to the existence of powerful algorithms; its existence will revolutionize modern day science by allowing true quantum simulations of systems that may be modelled classically only insufficiently due to an in-principle limitation of current computer technology. Recent progress in experiments with trapped single atomic ions showed that it should be possible to build a quantum computer using this technology.

A major challenge is the scaling of already existing technology beyond a token number of quantum bits. AIQT addressed the manipulation of single atoms in complicated arrays as an architecture for a quantum computer. The aim of this project was to provide an infrastructure to carry out experiments towards unprecedented motional control of a large number of single atoms inside ion trap arrays on a chip. As part of these experiments single atomic ions will be trapped using electric fields, shuttled inside a complicated array of trap electrodes and manipulated using laser beams.

Architectures for the implementation of an ion trap quantum computer were investigated by exploring nano- and micro-fabricated structures using techniques from micro-electromechanical device engineering. Furthermore, this project developed techniques to retain and control atoms during shuttling operations along complicated paths inside the array along with protocols to control a large number of quantum bits in such arrays. Finally, optimized ion trap geometries were developed that allow for simple transport of atomic ions in multi-dimensional arrays.

Reported by

UNIVERSITY OF SUSSEX
FALMER
United Kingdom
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