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Literature DB >> 15323739

Preparing high purity initial states for nuclear magnetic resonance quantum computing.

M S Anwar¹, D Blazina, H A Carteret, S B Duckett, T K Halstead, J A Jones, C M Kozak, R J K Taylor.

Abstract

Here we demonstrate how parahydrogen can be used to prepare a two-spin system in an almost pure state which is suitable for implementing nuclear magnetic resonance quantum computation. A 12 ns laser pulse is used to initiate a chemical reaction involving pure parahydrogen (the nuclear spin singlet of H2). The product, formed on the micros time scale, contains a hydrogen-derived two-spin system with an effective spin-state purity of 0.916. To achieve a comparable result by direct cooling would require an unmanageable (in the liquid state) temperature of 6.4 mK or an impractical magnetic field of 0.45 MT at room temperature. The resulting spin state has an entanglement of formation of 0.822 and cannot be described by local hidden variable models. Copyright 2004 The American Physical Society

Entities: Chemical

Year: 2004 PMID： 15323739 DOI： 10.1103/PhysRevLett.93.040501

Source DB: PubMed Journal: Phys Rev Lett ISSN： 0031-9007 Impact factor: 9.161

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Cited

6 in total

1. Delivering strong ¹H nuclear hyperpolarization levels and long magnetic lifetimes through signal amplification by reversible exchange.

Authors: Peter J Rayner; Michael J Burns; Alexandra M Olaru; Philip Norcott; Marianna Fekete; Gary G R Green; Louise A R Highton; Ryan E Mewis; Simon B Duckett
Journal: Proc Natl Acad Sci U S A Date: 2017-04-04 Impact factor: 11.205

Preparing high purity initial states for nuclear magnetic resonance quantum computing.

1. Delivering strong ¹H nuclear hyperpolarization levels and long magnetic lifetimes through signal amplification by reversible exchange.

2. Entanglement in a solid-state spin ensemble.

3. Strongly hyperpolarized gas from parahydrogen by rational design of ligand-capped nanoparticles.

4. The reaction of an iridium PNP complex with parahydrogen facilitates polarisation transfer without chemical change.

5. Over 50 % ¹H and ¹³C Polarization for Generating Hyperpolarized Metabolites-A para-Hydrogen Approach.

6. Quantum entanglement at ambient conditions in a macroscopic solid-state spin ensemble.

Preparing high purity initial states for nuclear magnetic resonance quantum computing.

1. Delivering strong 1H nuclear hyperpolarization levels and long magnetic lifetimes through signal amplification by reversible exchange.

2. Entanglement in a solid-state spin ensemble.

3. Strongly hyperpolarized gas from parahydrogen by rational design of ligand-capped nanoparticles.

4. The reaction of an iridium PNP complex with parahydrogen facilitates polarisation transfer without chemical change.

5. Over 50 % 1H and 13C Polarization for Generating Hyperpolarized Metabolites-A para-Hydrogen Approach.

6. Quantum entanglement at ambient conditions in a macroscopic solid-state spin ensemble.

1. Delivering strong ¹H nuclear hyperpolarization levels and long magnetic lifetimes through signal amplification by reversible exchange.

5. Over 50 % ¹H and ¹³C Polarization for Generating Hyperpolarized Metabolites-A para-Hydrogen Approach.