Robust parahydrogen-induced polarization at high concentrations
Robust parahydrogen-induced polarization at high concentrations
Parahydrogen-induced polarization (PHIP) is a potent technique for generating target molecules with high nuclear spin polarization. The PHIP process involves a chemical reaction between parahydrogen and a target molecule, followed by the transformation of nuclear singlet spin order into magnetization of a designated target nucleus through magnetic field manipulations. Although the singlet-to-magnetization polarization transfer process works effectively at moderate concentrations, it is observed to become much less efficient at high molar polarization, defined as the product of polarization and concentration. This strong dependence on the molar polarization is attributed to interference due to the field produced by the sample magnetization during polarization transfer, which leads to complex dynamics and can severely affect the scalability of the technique. We address this challenge with a pulse sequence that suppresses the influence of the distant dipolar field, while simultaneously achieving singlet-to-magnetization polarization transfer to the desired target spins, free from restrictions on the molar polarization.
Dagys, Laurynas
0de61597-b152-4bee-a934-123a9d2de883
Korzeczek, Martin C.
eaad896c-813e-4bb0-b8d5-773b6040444b
Parker, Anna J.
c1f6aec8-aad3-47e7-b3e4-566d0c43f14b
Eills, James
23130b21-68fa-4c8b-9399-e55f2e71ef36
Blanchard, John W.
3bb7de6e-f147-4527-9b1c-fbf8cb138f47
Bengs, Christian
cd3282d0-27ad-444f-bcb4-70eeab0029b9
Levitt, Malcolm H.
bcc5a80a-e5c5-4e0e-9a9a-249d036747c3
Knecht, Stephan
7618faf5-ce64-4c20-9b57-9c30d300cfb7
Schwartz, Ilai
a00e1bfe-1e2e-4de5-a466-dd5b16921b36
Plenio, Martin B.
462a51d3-8ffd-4085-99bc-8559933aab0c
26 July 2024
Dagys, Laurynas
0de61597-b152-4bee-a934-123a9d2de883
Korzeczek, Martin C.
eaad896c-813e-4bb0-b8d5-773b6040444b
Parker, Anna J.
c1f6aec8-aad3-47e7-b3e4-566d0c43f14b
Eills, James
23130b21-68fa-4c8b-9399-e55f2e71ef36
Blanchard, John W.
3bb7de6e-f147-4527-9b1c-fbf8cb138f47
Bengs, Christian
cd3282d0-27ad-444f-bcb4-70eeab0029b9
Levitt, Malcolm H.
bcc5a80a-e5c5-4e0e-9a9a-249d036747c3
Knecht, Stephan
7618faf5-ce64-4c20-9b57-9c30d300cfb7
Schwartz, Ilai
a00e1bfe-1e2e-4de5-a466-dd5b16921b36
Plenio, Martin B.
462a51d3-8ffd-4085-99bc-8559933aab0c
Dagys, Laurynas, Korzeczek, Martin C., Parker, Anna J., Eills, James, Blanchard, John W., Bengs, Christian, Levitt, Malcolm H., Knecht, Stephan, Schwartz, Ilai and Plenio, Martin B.
(2024)
Robust parahydrogen-induced polarization at high concentrations.
Science Advances, 10 (30), [eado0373].
(doi:10.1126/sciadv.ado0373).
Abstract
Parahydrogen-induced polarization (PHIP) is a potent technique for generating target molecules with high nuclear spin polarization. The PHIP process involves a chemical reaction between parahydrogen and a target molecule, followed by the transformation of nuclear singlet spin order into magnetization of a designated target nucleus through magnetic field manipulations. Although the singlet-to-magnetization polarization transfer process works effectively at moderate concentrations, it is observed to become much less efficient at high molar polarization, defined as the product of polarization and concentration. This strong dependence on the molar polarization is attributed to interference due to the field produced by the sample magnetization during polarization transfer, which leads to complex dynamics and can severely affect the scalability of the technique. We address this challenge with a pulse sequence that suppresses the influence of the distant dipolar field, while simultaneously achieving singlet-to-magnetization polarization transfer to the desired target spins, free from restrictions on the molar polarization.
Text
LD-LGPHIP-SciAdv-accepted
- Accepted Manuscript
Restricted to Repository staff only
Request a copy
Text
sciadv.ado0373
- Version of Record
More information
Accepted/In Press date: 18 June 2024
Published date: 26 July 2024
Identifiers
Local EPrints ID: 492789
URI: http://eprints.soton.ac.uk/id/eprint/492789
ISSN: 2375-2548
PURE UUID: 94ceb572-574f-4997-b179-b4f762d48da1
Catalogue record
Date deposited: 14 Aug 2024 16:32
Last modified: 15 Aug 2024 01:37
Export record
Altmetrics
Contributors
Author:
Laurynas Dagys
Author:
Martin C. Korzeczek
Author:
Anna J. Parker
Author:
James Eills
Author:
John W. Blanchard
Author:
Christian Bengs
Author:
Stephan Knecht
Author:
Ilai Schwartz
Author:
Martin B. Plenio
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics