Exciting Opportunities for Solid-State 95Mo NMR Studies of MoS2 Nanostructures in Materials Research from a Low to an Ultrahigh Magnetic Field (35.2 T)

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Exciting Opportunities for Solid-State 95Mo NMR Studies of MoS2 Nanostructures in Materials Research from a Low to an Ultrahigh Magnetic Field (35.2 T). / Jakobsen, Hans J.; Bildsøe, Henrik; Bondesgaard, Martin; Iversen, Bo B.; Brorson, Michael; Larsen, Flemming H.; Gan, Zhehong; Hung, Ivan.

In: Journal of Physical Chemistry C, Vol. 125, No. 14, 2021, p. 7824-7838.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Jakobsen, HJ, Bildsøe, H, Bondesgaard, M, Iversen, BB, Brorson, M, Larsen, FH, Gan, Z & Hung, I 2021, 'Exciting Opportunities for Solid-State 95Mo NMR Studies of MoS2 Nanostructures in Materials Research from a Low to an Ultrahigh Magnetic Field (35.2 T)', Journal of Physical Chemistry C, vol. 125, no. 14, pp. 7824-7838. https://doi.org/10.1021/acs.jpcc.0c10522

APA

Jakobsen, H. J., Bildsøe, H., Bondesgaard, M., Iversen, B. B., Brorson, M., Larsen, F. H., Gan, Z., & Hung, I. (2021). Exciting Opportunities for Solid-State 95Mo NMR Studies of MoS2 Nanostructures in Materials Research from a Low to an Ultrahigh Magnetic Field (35.2 T). Journal of Physical Chemistry C, 125(14), 7824-7838. https://doi.org/10.1021/acs.jpcc.0c10522

Vancouver

Jakobsen HJ, Bildsøe H, Bondesgaard M, Iversen BB, Brorson M, Larsen FH et al. Exciting Opportunities for Solid-State 95Mo NMR Studies of MoS2 Nanostructures in Materials Research from a Low to an Ultrahigh Magnetic Field (35.2 T). Journal of Physical Chemistry C. 2021;125(14):7824-7838. https://doi.org/10.1021/acs.jpcc.0c10522

Author

Jakobsen, Hans J. ; Bildsøe, Henrik ; Bondesgaard, Martin ; Iversen, Bo B. ; Brorson, Michael ; Larsen, Flemming H. ; Gan, Zhehong ; Hung, Ivan. / Exciting Opportunities for Solid-State 95Mo NMR Studies of MoS2 Nanostructures in Materials Research from a Low to an Ultrahigh Magnetic Field (35.2 T). In: Journal of Physical Chemistry C. 2021 ; Vol. 125, No. 14. pp. 7824-7838.

Bibtex

@article{8fea3dda7eeb40aa97b1691aa3fc8e48,
title = "Exciting Opportunities for Solid-State 95Mo NMR Studies of MoS2 Nanostructures in Materials Research from a Low to an Ultrahigh Magnetic Field (35.2 T)",
abstract = "Solid-state, natural-abundance Mo-95 NMR experiments of four different MoS2 materials have been performed on a magnet at B-0 = 19.6 T and on a new series-connected hybrid magnet at 35.2 T. Employing two different 2H-MoS2 (2H phase) materials, a {"}pseudo-amorphous{"} MoS2 nanomaterial and a MoS2 layer on an Al2O3 support of a hydrodesulfurization (HDS) catalyst, has enabled the introduction of solid-state Mo-95 NMR as an important analytical tool in the study of MoS2 nanomaterials. Mo-95 spin-lattice relaxation time (T-1) studies of 160- and 4-layer 2H-MoS2 samples at 19.6 and 35.2 T show their relaxation rate (1/T-1) increase in proportion to B-0(2). This is in accord with chemical shift anisotropy (CSA) relaxation, which is the dominant T-1(Mo-95) mechanism, with a large Mo-95 CSA of 1025 ppm determined for all four MoS2 nanomaterials. The dominant CSA mechanism suggests that the MoS2 band gap electrons are delocalized throughout the lattice-layer structures, thereby acting as a fast modulation source (omega(o)tau(c) << 1) for Mo-95 CSA in 2H-MoS2. A decrease in T-1(Mo-95) is observed for an increase in the B-0 field and for a decrease in the number of 2H-MoS2 layers. All four nanomaterials exhibit identical Mo-95 electric-field gradient (EFG) parameters. The T-1 results account for the several failures in retrieving the Mo-95 spectral EFG and CSA parameters for multilayer 2H-MoS2 samples in the pioneering solid-state Mo-95 NMR studies performed during the past 2 decades (1990-2010) because of the extremely long T-1(Mo-95) = similar to 200-250 s observed at a low B-0 (similar to 9.4 T) used at that time. Much shorter T-1(Mo-95) values are observed even at 19.6 T for the {"}pseudo-amorphous{"} and the HDS catalyst (MoS2-Al2O3 support) MoS2 nanomaterials. These allowed obtaining useful solid-state Mo-95 NMR spectra for these two samples at 19.6 T in a few to",
keywords = "QCPMG-MAS NMR, QUADRUPOLAR NUCLEI, SPECTROSCOPY, CATALYSTS, TERM",
author = "Jakobsen, {Hans J.} and Henrik Bilds{\o}e and Martin Bondesgaard and Iversen, {Bo B.} and Michael Brorson and Larsen, {Flemming H.} and Zhehong Gan and Ivan Hung",
year = "2021",
doi = "10.1021/acs.jpcc.0c10522",
language = "English",
volume = "125",
pages = "7824--7838",
journal = "The Journal of Physical Chemistry Part C",
issn = "1932-7447",
publisher = "American Chemical Society",
number = "14",

}

RIS

TY - JOUR

T1 - Exciting Opportunities for Solid-State 95Mo NMR Studies of MoS2 Nanostructures in Materials Research from a Low to an Ultrahigh Magnetic Field (35.2 T)

AU - Jakobsen, Hans J.

AU - Bildsøe, Henrik

AU - Bondesgaard, Martin

AU - Iversen, Bo B.

AU - Brorson, Michael

AU - Larsen, Flemming H.

AU - Gan, Zhehong

AU - Hung, Ivan

PY - 2021

Y1 - 2021

N2 - Solid-state, natural-abundance Mo-95 NMR experiments of four different MoS2 materials have been performed on a magnet at B-0 = 19.6 T and on a new series-connected hybrid magnet at 35.2 T. Employing two different 2H-MoS2 (2H phase) materials, a "pseudo-amorphous" MoS2 nanomaterial and a MoS2 layer on an Al2O3 support of a hydrodesulfurization (HDS) catalyst, has enabled the introduction of solid-state Mo-95 NMR as an important analytical tool in the study of MoS2 nanomaterials. Mo-95 spin-lattice relaxation time (T-1) studies of 160- and 4-layer 2H-MoS2 samples at 19.6 and 35.2 T show their relaxation rate (1/T-1) increase in proportion to B-0(2). This is in accord with chemical shift anisotropy (CSA) relaxation, which is the dominant T-1(Mo-95) mechanism, with a large Mo-95 CSA of 1025 ppm determined for all four MoS2 nanomaterials. The dominant CSA mechanism suggests that the MoS2 band gap electrons are delocalized throughout the lattice-layer structures, thereby acting as a fast modulation source (omega(o)tau(c) << 1) for Mo-95 CSA in 2H-MoS2. A decrease in T-1(Mo-95) is observed for an increase in the B-0 field and for a decrease in the number of 2H-MoS2 layers. All four nanomaterials exhibit identical Mo-95 electric-field gradient (EFG) parameters. The T-1 results account for the several failures in retrieving the Mo-95 spectral EFG and CSA parameters for multilayer 2H-MoS2 samples in the pioneering solid-state Mo-95 NMR studies performed during the past 2 decades (1990-2010) because of the extremely long T-1(Mo-95) = similar to 200-250 s observed at a low B-0 (similar to 9.4 T) used at that time. Much shorter T-1(Mo-95) values are observed even at 19.6 T for the "pseudo-amorphous" and the HDS catalyst (MoS2-Al2O3 support) MoS2 nanomaterials. These allowed obtaining useful solid-state Mo-95 NMR spectra for these two samples at 19.6 T in a few to

AB - Solid-state, natural-abundance Mo-95 NMR experiments of four different MoS2 materials have been performed on a magnet at B-0 = 19.6 T and on a new series-connected hybrid magnet at 35.2 T. Employing two different 2H-MoS2 (2H phase) materials, a "pseudo-amorphous" MoS2 nanomaterial and a MoS2 layer on an Al2O3 support of a hydrodesulfurization (HDS) catalyst, has enabled the introduction of solid-state Mo-95 NMR as an important analytical tool in the study of MoS2 nanomaterials. Mo-95 spin-lattice relaxation time (T-1) studies of 160- and 4-layer 2H-MoS2 samples at 19.6 and 35.2 T show their relaxation rate (1/T-1) increase in proportion to B-0(2). This is in accord with chemical shift anisotropy (CSA) relaxation, which is the dominant T-1(Mo-95) mechanism, with a large Mo-95 CSA of 1025 ppm determined for all four MoS2 nanomaterials. The dominant CSA mechanism suggests that the MoS2 band gap electrons are delocalized throughout the lattice-layer structures, thereby acting as a fast modulation source (omega(o)tau(c) << 1) for Mo-95 CSA in 2H-MoS2. A decrease in T-1(Mo-95) is observed for an increase in the B-0 field and for a decrease in the number of 2H-MoS2 layers. All four nanomaterials exhibit identical Mo-95 electric-field gradient (EFG) parameters. The T-1 results account for the several failures in retrieving the Mo-95 spectral EFG and CSA parameters for multilayer 2H-MoS2 samples in the pioneering solid-state Mo-95 NMR studies performed during the past 2 decades (1990-2010) because of the extremely long T-1(Mo-95) = similar to 200-250 s observed at a low B-0 (similar to 9.4 T) used at that time. Much shorter T-1(Mo-95) values are observed even at 19.6 T for the "pseudo-amorphous" and the HDS catalyst (MoS2-Al2O3 support) MoS2 nanomaterials. These allowed obtaining useful solid-state Mo-95 NMR spectra for these two samples at 19.6 T in a few to

KW - QCPMG-MAS NMR

KW - QUADRUPOLAR NUCLEI

KW - SPECTROSCOPY

KW - CATALYSTS

KW - TERM

U2 - 10.1021/acs.jpcc.0c10522

DO - 10.1021/acs.jpcc.0c10522

M3 - Journal article

C2 - 34262634

VL - 125

SP - 7824

EP - 7838

JO - The Journal of Physical Chemistry Part C

JF - The Journal of Physical Chemistry Part C

SN - 1932-7447

IS - 14

ER -

ID: 272062035