Indirectly detected satellite-transition quadrupolar NMR via progressive saturation of the proton reservoir

Tamar Wolf, Anna Eden Kossoy, Lucio Frydman*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

4 Citations (Scopus)

Abstract

Static satellite-transitions (ST) NMR line shapes from half-integer quadrupolar nuclei could be very informative: they can deliver information on local motions over a wide range of timescales, and can report on small changes in the local electronic environments as reflected by the quadrupolar parameters. Satellite transitions, however, are typically “invisible” for half-integer quadrupolar nuclei due to their sheer breadth, leading to low signal-to-noise ratio –especially for unreceptive low-gamma or dilute quadrupolar nuclei. Very recently we have introduced a method for enhancing the NMR sensitivity of unreceptive X nuclei in static solids dubbed PROgressive Saturation of the Proton Reservoir (PROSPR), which opens the possibility of magnifying the signals from such spins by repeatedly imprinting frequency-selective X-driven depolarizations on the much more sensitive 1H NMR signal. Here, we show that PROSPR's efficacy is high enough for enabling the detection of static ST NMR for challenging species like 35Cl, 33S and even 17O –all at natural-abundance. The ensuing ST-PROSPR NMR experiment thus opens new approaches to probe ultra-wideline (6–8 MHz wide) spectra; these highly pronounced anisotropies can in turn deliver new vistas about dynamic changes in solids, as here illustrated by tracking ST line shapes as a function of temperature during thermally-driven events.
Original languageEnglish
Article number101862
Number of pages8
JournalSolid State Nuclear Magnetic Resonance
Volume125
Early online date15 Mar 2023
DOIs
Publication statusPublished - Jun 2023

Funding

We thank Dr. Michael J. Jaroszewicz (Weizmann Institute) for extensive advice, Dr. Elton Montrazi (Weizmann Institute) for technical help, and to Dr. Sean Holmes (Florida State Univ.), Prof. Gang Wu (Queens Univ.) and Prof. Ilya Kuprov (University of Southampton) for useful discussions. This work was funded by the Israel Science Foundation Grant 1874/22 , the EU Horizon 2020 program (FET-OPEN Grant 828946 , PATHOS), and the Perlman Family Foundation . T.W. acknowledges the Clore Foundation for a graduate student fellowship. L.F. holds the Bertha and Isadore Gudelsky Professorial Chair and Heads the Clore Institute for High-Field Magnetic Resonance Imaging and Spectroscopy, whose support is also acknowledged. We thank Dr. Michael J. Jaroszewicz (Weizmann Institute) for extensive advice, Dr. Elton Montrazi (Weizmann Institute) for technical help, and to Dr. Sean Holmes (Florida State Univ.), Prof. Gang Wu (Queens Univ.) and Prof. Ilya Kuprov (University of Southampton) for useful discussions. This work was funded by the Israel Science Foundation Grant 1874/22, the EU Horizon 2020 program (FET-OPEN Grant 828946, PATHOS), and the Perlman Family Foundation. T.W. acknowledges the Clore Foundation for a graduate student fellowship. L.F. holds the Bertha and Isadore Gudelsky Professorial Chair and Heads the Clore Institute for High-Field Magnetic Resonance Imaging and Spectroscopy, whose support is also acknowledged.

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