Complete H-1 resonance assignment of beta-maltose from H-1-H-1 DQ-SQ CRAMPS and H-1 (DQ-DUMBO)-C-13 SQ refocused INEPT 2D solid-state NMR spectra and first principles GIPAW calculations

abstract

A disaccharide is a challenging case for high-resolution H-1 solid-state NMR because of the 24 distinct protons (14 aliphatic and 10 OH) having H-1 chemical shifts that all fall within a narrow range of approximately 3 to 7 ppm. High-resolution H-1 (500 MHz) double-quantum (DQ) combined rotation and multiple pulse sequence (CRAMPS) solid-state NMR spectra of beta-maltose monohydrate are presented. H-1-H-1 DQ-SQ CRAMPS spectra are presented together with H-1 (DQ)-C-13 correlation spectra obtained with a new pulse sequence that correlates a high-resolution H-1 DQ dimension with a C-13 single quantum (SQ) dimension using the refocused INEPT pulse-sequence element to transfer magnetization via one-bond C-13-H-1 J couplings. Compared to the observation of only a single broad peak in a H-1 DQ spectrum recorded at 30 kHz magic-angle spinning (MAS), the use of DUMBO H-1 homonuclear decoupling in the H-1 DQ CRAMPS experiment allows the resolution of distinct DQ correlation peaks which, in combination with first-principles chemical shift calculations based on the GIPAW (Gauge Including Projector Augmented Waves) plane-wave pseudopotential approach, enables the assignment of the H-1 resonances to the 24 distinct protons. We believe this to be the first experimental solid-state NMR determination of the hydroxyl OH H-1 chemical shifts for a simple sugar. Variable-temperature H-1-H-1 DQ CRAMPS spectra reveal small increases in the H-1 chemical shifts of the OH resonances upon decreasing the temperature from 348 K to 248 K.

keywords

POWDER DIFFRACTION DATA; QUANTUM-CHEMICAL CALCULATIONS; NUCLEAR-MAGNETIC-RESONANCE; PROTON-PROTON PROXIMITIES; DENSITY-FUNCTIONAL THEORY; PI-PI PACKING; CRYSTAL-STRUCTURE; O-17 NMR; 1ST-PRINCIPLES CALCULATION; CORRELATION SPECTROSCOPY

subject category

Chemistry; Physics

authors

Webber, AL; Elena, B; Griffin, JM; Yates, JR; Pham, TN; Mauri, F; Pickard, CJ; Gil, AM; Stein, R; Lesage, A; Emsley, L; Brown, SP

our authors

acknowledgements

Funding from EPSRC (UK) and Fundacao para a Ciencia e a Tecnologia, Portugal (POCTI/33075/QUI/2000) is acknowledged. The 500 MHz spectrometer at Warwick used in this research was funded by Birmingham Science City with support from Advantage West Midlands (AWM). Computational resources were provided by the Cambridge-Cranfield HPCF. Financial support by the Access to Research Infrastructures activity in the 6th Framework Programme of the EC (Contract #RII3-026145, EU-NMR) for conducting the research is gratefully acknowledged.

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