Advances in NMR and MRI of Materials

doi:10.3390/books978-3-0365-7620-6

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Advances in NMR and MRI of Materials

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May 2023

388 pages

ISBN978-3-0365-7621-3 (Hardback)
ISBN978-3-0365-7620-6 (PDF)

https://doi.org/10.3390/books978-3-0365-7620-6

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This book is a reprint of the Special Issue Advances in NMR and MRI of Materials that was published in

Chemistry & Materials Science

Medicine & Pharmacology

Summary

The development of science has led to the emergence of many new modern materials, which also require more advanced tools for their characterization and analysis. NMR and MRI are certainly among such tools, also due to their continuous development, which has made them more powerful, versatile, and sensitive. With these advances, these two techniques have been able to address many open problems associated with the emergence of new materials.This reprint comprises a collection of advanced NMR and MRI techniques and methods, together with a demonstration of their application to the target materials for which they were designed and optimized. These are presented in 25 original, peer-reviewed articles for the Special Issue in the MDPI journal Molecules. The topics covered include MR methods in pharmaceutical research, NMR in cement research, MR methods in wood research, diffusion in materials, characterization of materials by NMR relaxometry, NMR spectroscopy of materials, and MRI of materials.

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Keywords

lamellar 2D zeolites; pillared zeolites; mordenite; ZSM-5; CTAB; NMR; magnetic resonance imaging contrast agents; renal clearance; nanodots; gadolinium (III)-based composites; cement hydration; titanium dioxide TiO₂; NMR; ultrasonic; calorimetry; diffusion; PGSE; NMR; Rouse; reptation; hydrophilic matrix tablets; magnetic resonance; hydrogel; drug release; biorelevant dynamic conditions; foam flow; magnetic resonance imaging; velocity mapping; pipe flow; two-phase flow; hyperpolarization; magnetic resonance imaging; flip angle; plasticizer; PVC; identification; quantification; non-deuterated solvent; low-field NMR spectroscopy; gabapentin; impurity A; validation; limit of the quantitation; linearity; accuracy; repeatability; precision; specificity; robustness; qNMR; HPLC; low field NMR; Inverse Laplace Transform; L-Curve regularization; confined liquid; relaxometry; drying process; solid-state NMR spectroscopy; porous material; drug delivery system; heteronuclei; magnetic resonance imaging (MRI); relaxation times; beech (Fagus sylvatica); wood; moisture content (MC); carthamin-3′potassium salt; green metallic luster; fermented safflower petal tablet; magnetic resonance imaging; natural soil material; fast relaxation times; water content; water flow; asphaltenes; maltenes; NMR; relaxation; diffusion; NMR relaxometry; cement hydration; accelerators; pore evolution; partially saturated; fractal dimension; electrical conductivity; anisotropy; magnetic resonance imaging (MRI); diffusion tensor imaging (DTI); conductivity tensor imaging (CTI); NMR diffusometry; zeolites; heterogeneous catalysis sugar conversion; biomolecules; [Pyr₁₃][Tf₂N]; [Pyr₁₆][Tf₂N]; MAS; CPMG; 13-interval PGSTE; VXC72 carbon black; diffusion-NMR; Ionic liquids; polyoxometalates; nuclear magnetic resonance imaging; paramagnetic relaxation enhancement; lanthanides; relaxivity; dysprosium; erbium; time-domain NMR; dipolar echoes; polymerization reaction; epoxy resin; autocatalytic reaction; budesonide; 22R and 22S epimers; identification; quantification; qNMR; HPLC; archaeological wood; silane; siloxane; wood consolidation; 2D NMR; chemical reactivity; solution-state NMR; wood conservation; waterlogged wood; cement hydration; induction period; accelerator; NMR relaxometry; Fast Field Cycling; 3-Tau model; gradient broadening; profile; hydrogel; swelling