The development of new superconducting ceramic materials, which maintain the superconductivity at very intense magnetic fields, has prompted the development of a new generation of highly homogeneous high field magnets that has trespassed the magnetic field attainable with the previous generation of instruments. But how can biomolecular NMR benefit from this? In this work, we review a few of the notable applications that, we expect, will be blooming thanks to this newly available technology.
Biomolecular NMR at 1.2 GHz / Lucia Banci, Letizia Barbieri, Vito Calderone, Francesca Cantini, Linda Cerofolini, Simone Ciofi-Baffoni, Isabella C. Felli, Marco Fragai, Moreno Lelli, Claudio Luchinat, Enrico Luchinat, Giacomo Parigi, Mario Piccioli, Roberta Pierattelli, Enrico Ravera, Antonio Rosato, Leonardo Tenori, Paola Turano. - ELETTRONICO. - (2020). [10.48550/arXiv.1910.07462]
Biomolecular NMR at 1.2 GHz
Lucia Banci;Letizia Barbieri;Vito Calderone;Francesca Cantini;Linda Cerofolini;Simone Ciofi-Baffoni;Isabella C. Felli;Marco Fragai;Moreno Lelli;Claudio Luchinat;Enrico Luchinat;Giacomo Parigi;Mario Piccioli;Roberta Pierattelli;Enrico Ravera;Antonio Rosato;Leonardo Tenori;Paola Turano
2020
Abstract
The development of new superconducting ceramic materials, which maintain the superconductivity at very intense magnetic fields, has prompted the development of a new generation of highly homogeneous high field magnets that has trespassed the magnetic field attainable with the previous generation of instruments. But how can biomolecular NMR benefit from this? In this work, we review a few of the notable applications that, we expect, will be blooming thanks to this newly available technology.
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