Dynamics of Cellulose−Water Interfaces:  NMR Spin−Lattice Relaxation Times Calculated from Atomistic Computer Simulations

Solid-state nuclear magnetic resonance (CP/MAS 13C NMR) spectroscopy has often been used to study cellulose structure, but some features of the cellulose NMR spectrum are not yet fully understood. One such feature is a doublet around 84 ppm, a signal that has been proposed to originate from C4 atoms...

Full description

Saved in:
Bibliographic Details
Published in:The journal of physical chemistry. B 2008-03, Vol.112 (9), p.2590-2595
Main Authors: Bergenstråhle, Malin, Wohlert, Jakob, Larsson, Per Tomas, Mazeau, Karim, Berglund, Lars A
Format: Article
Language:English
Subjects:
Algorithms
Carbon - chemistry
Cellulose - chemistry
cellulose-water interface
Chemistry
Computer Simulation
Fysikalisk kemi
Kemi
Magnetic Resonance Spectroscopy - methods
Models, Molecular
molecular dynamics
NATURAL SCIENCES
NATURVETENSKAP
Organic chemistry
Organisk kemi
Physical chemistry
Polymer chemistry
Polymerkemi
Rotation
spin-lattice relaxation times
Surface Properties
Water - chemistry
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Solid-state nuclear magnetic resonance (CP/MAS 13C NMR) spectroscopy has often been used to study cellulose structure, but some features of the cellulose NMR spectrum are not yet fully understood. One such feature is a doublet around 84 ppm, a signal that has been proposed to originate from C4 atoms at cellulose fibril surfaces. The two peaks yield different T 1, differing by approximately a factor of 2 at 75 MHz. In this study, we calculate T 1 from C4−H4 vector dynamics obtained from molecular dynamics computer simulations of cellulose I β−water interfacial systems. Calculated and experimentally obtained T 1 values for C4 atoms in surface chains fell within the same order of magnitude, 3−20 s. This means that the applied force field reproduces relevant surface dynamics for the cellulose−water interface sufficiently well. Furthermore, a difference in T 1 of about a factor of 2 in the range of Larmor frequencies 25−150 MHz was found for C4 atoms in chains located on top of two different crystallographic planes, namely, (110) and (11̄0). A previously proposed explanation that the C4 peak doublet could derive from surfaces parallel to different crystallographic planes is herewith strengthened by computationally obtained evidence. Another suggested basis for this difference is that the doublet originates from C4 atoms located in surface anhydro-glucose units with hydroxymethyl groups pointing either inward or outward. This was also tested within this study but was found to yield no difference in calculated T 1.
ISSN:1520-6106
1520-5207
1520-5207
DOI:10.1021/jp074641t