SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4225915997> ?p ?o ?g. }

Showing items 1 to 100 of ±123 with 100 items per page.

W4225915997 endingPage "130" @default.
W4225915997 startingPage "116" @default.
W4225915997 abstract "Multinuclear NMR studies of the gaseous mixtures that involve volatile compounds and 3He atoms are featured in this review. The precise analyses of 3He and other nuclei resonance frequencies show linear dependencies on gas density. Extrapolation of the gas phase results to the zero-pressure limit gives the ν0(3He) and ν0(nX) resonance frequencies of nuclei in a single 3-helium atom and nuclei in molecules at a given temperature. The NMR frequency comparison method provides an approach for determining different nuclear magnetic moments. The application of quantum chemical shielding calculations, which include a more complete and careful theoretical treatment, allows the shielding of isolated molecules to be achieved with great accuracy and precision. They are used for the evaluation of nuclear moments, without shielding impacts on the bare nuclei, for: 10/11B, 13C, 14N, 17O, 19F, 21Ne, 29Si, 31P, 33S, 35/37Cl, 33S, 83Kr, 129/131Xe, and 183W. On the other hand, new results of nuclear moments were used for the reevaluation of absolute nuclear magnetic shielding in the molecules under study. Additionally, 3He gas in water solutions of lithium and sodium salts was used for measuring 6/7Li and 23Na magnetic moments and reevaluating the shielding parameters of Li+ and Na+ water-solvated cations. In this paper, guest 3He atoms that play a role in probing the electron density in many host macromolecules are also presented." @default.
W4225915997 created "2022-05-05" @default.
W4225915997 creator A5017958017 @default.
W4225915997 date "2022-04-28" @default.
W4225915997 modified "2023-09-30" @default.
W4225915997 title "Probing Nuclear Dipole Moments and Magnetic Shielding Constants through 3-Helium NMR Spectroscopy" @default.
W4225915997 cites W1498016910 @default.
W4225915997 cites W1879021522 @default.
W4225915997 cites W1901715948 @default.
W4225915997 cites W191718923 @default.
W4225915997 cites W1960483649 @default.
W4225915997 cites W1965228196 @default.
W4225915997 cites W1976034720 @default.
W4225915997 cites W1983228580 @default.
W4225915997 cites W1988279677 @default.
W4225915997 cites W1989572488 @default.
W4225915997 cites W1990356040 @default.
W4225915997 cites W1996954258 @default.
W4225915997 cites W2016277339 @default.
W4225915997 cites W2020292804 @default.
W4225915997 cites W2026986174 @default.
W4225915997 cites W2032969762 @default.
W4225915997 cites W2037363234 @default.
W4225915997 cites W2041960878 @default.
W4225915997 cites W2044938603 @default.
W4225915997 cites W2050306466 @default.
W4225915997 cites W2050438876 @default.
W4225915997 cites W2062347665 @default.
W4225915997 cites W2072724894 @default.
W4225915997 cites W2081659603 @default.
W4225915997 cites W2086723506 @default.
W4225915997 cites W2087566704 @default.
W4225915997 cites W2094659919 @default.
W4225915997 cites W2095231627 @default.
W4225915997 cites W2114736202 @default.
W4225915997 cites W2130544282 @default.
W4225915997 cites W2147061689 @default.
W4225915997 cites W2168170401 @default.
W4225915997 cites W2294080037 @default.
W4225915997 cites W2325341884 @default.
W4225915997 cites W2325970725 @default.
W4225915997 cites W2326538667 @default.
W4225915997 cites W2334958954 @default.
W4225915997 cites W2471189962 @default.
W4225915997 cites W2518973955 @default.
W4225915997 cites W2739965019 @default.
W4225915997 cites W2763294859 @default.
W4225915997 cites W2766811610 @default.
W4225915997 cites W2769890435 @default.
W4225915997 cites W2774573371 @default.
W4225915997 cites W2885028691 @default.
W4225915997 cites W2905680454 @default.
W4225915997 cites W2950610683 @default.
W4225915997 cites W2952396706 @default.
W4225915997 cites W2969718427 @default.
W4225915997 cites W2992143050 @default.
W4225915997 cites W3004900645 @default.
W4225915997 cites W3044751042 @default.
W4225915997 cites W3105103882 @default.
W4225915997 cites W3105347848 @default.
W4225915997 cites W3108042584 @default.
W4225915997 cites W3121817802 @default.
W4225915997 cites W3133706450 @default.
W4225915997 cites W3215393118 @default.
W4225915997 cites W4226476853 @default.
W4225915997 cites W4247551358 @default.
W4225915997 cites W574269482 @default.
W4225915997 doi "https://doi.org/10.3390/physchem2020009" @default.
W4225915997 hasPublicationYear "2022" @default.
W4225915997 type Work @default.
W4225915997 citedByCount "2" @default.
W4225915997 countsByYear W42259159972023 @default.
W4225915997 crossrefType "journal-article" @default.
W4225915997 hasAuthorship W4225915997A5017958017 @default.
W4225915997 hasBestOaLocation W42259159971 @default.
W4225915997 hasConcept C121332964 @default.
W4225915997 hasConcept C159985019 @default.
W4225915997 hasConcept C173523689 @default.
W4225915997 hasConcept C178790620 @default.
W4225915997 hasConcept C184779094 @default.
W4225915997 hasConcept C185592680 @default.
W4225915997 hasConcept C192562407 @default.
W4225915997 hasConcept C2265751 @default.
W4225915997 hasConcept C26873012 @default.
W4225915997 hasConcept C32909587 @default.
W4225915997 hasConcept C46141821 @default.
W4225915997 hasConcept C54553102 @default.
W4225915997 hasConcept C546029482 @default.
W4225915997 hasConcept C66974803 @default.
W4225915997 hasConceptScore W4225915997C121332964 @default.
W4225915997 hasConceptScore W4225915997C159985019 @default.
W4225915997 hasConceptScore W4225915997C173523689 @default.
W4225915997 hasConceptScore W4225915997C178790620 @default.
W4225915997 hasConceptScore W4225915997C184779094 @default.
W4225915997 hasConceptScore W4225915997C185592680 @default.
W4225915997 hasConceptScore W4225915997C192562407 @default.
W4225915997 hasConceptScore W4225915997C2265751 @default.
W4225915997 hasConceptScore W4225915997C26873012 @default.