Measuring the crystallinity index of cellulose by solid state 13C nuclear magnetic resonance

Park, Sunkyu; Johnson, David K.; Ishizawa, Claudia I.; Parilla, Philip A.; Davis, Mark F.

doi:10.1007/s10570-009-9321-1

Cited by 230 publications

(166 citation statements)

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“…Considering that in WAXS the peak-height crystallinity calculation method gave significantly higher values compared to other X-ray and NMR methods (Park et al 2009) the authors make the following suggestion based on the findings of the present investigation. It is proposed that, in the simple peak height method, the amorphous contribution be measured at *21°instead of *18°.…”

Section: Ball Milled Samplesmentioning

confidence: 67%

“…Higher crystallinity by WAXS methods has been reported in the literature. For example, Park et al (2009) used three X-ray methods (peak height, peak deconvolution, and amorphous contribution subtraction) to calculate the crystallinity index of 11 cellulose samples. The three methods produced significantly different crystallinity indexes.…”

Section: Ball Milled Samplesmentioning

confidence: 99%

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Cellulose I crystallinity determination using FT–Raman spectroscopy: univariate and multivariate methods

2010

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Two new methods based on FT-Raman spectroscopy, one simple, based on band intensity ratio, and the other using a partial least squares (PLS) regression model, are proposed to determine cellulose I crystallinity. In the simple method, crystallinity in cellulose I samples was determined based on univariate regression that was first developed using the Raman band intensity ratio of the 380 and 1,096 cm -1 bands. For calibration purposes, 80.5% crystalline and 120-min milled (0% crystalline) Whatman CC31 and six cellulose mixtures produced with crystallinities in the range 10.9-64% were used. When intensity ratios were plotted against crystallinities of the calibration set samples, the plot showed a linear correlation (coefficient of determination R 2 = 0.992). Average standard error calculated from replicate Raman acquisitions indicated that the cellulose Raman crystallinity model was reliable. Crystallinities of the cellulose mixtures samples were also calculated from X-ray diffractograms using the amorphous contribution subtraction (Segal) method and it was found that the Raman model was better. Additionally, using both Raman and X-ray techniques, sample crystallinities were determined from partially crystalline cellulose samples that were generated by grinding Whatman CC31 in a vibratory mill. The two techniques showed significant differences. In the second approach, successful Raman PLS regression models for crystallinity, covering the 0-80.5% range, were generated from the ten calibration set Raman spectra. Both univariateRaman and WAXS determined crystallinities were used as references. The calibration models had strong relationships between determined and predicted crystallinity values (R 2 = 0.998 and 0.984, for univariateRaman and WAXS referenced models, respectively). Compared to WAXS, univariate-Raman referenced model was found to be better (root mean square error of calibration (RMSEC) and root mean square error of prediction (RMSEP) values of 6.1 and 7.9% vs. 1.8 and 3.3%, respectively). It was concluded that either of the two Raman methods could be used for cellulose I crystallinity determination in cellulose samples.

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Section: Ball Milled Samplesmentioning

confidence: 67%

Section: Ball Milled Samplesmentioning

confidence: 99%

Cellulose I crystallinity determination using FT–Raman spectroscopy: univariate and multivariate methods

2010

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“…However, monosaccharide and disaccharide models differ greatly from a cellulose microfibril and as a result there were significant differences (* 10 ppm) between the calculated and observed d 13 C values. For example, compared to the cellulose experimental d 13 C4 values of 79-93 ppm (Park et al 2009), their calculated d 13 C4 were between * 65 and * 75 ppm. To improve the agreement between observation and calculation, in the work presented here, we utilized an Ib cellulose model system containing 12 cellotetraose chains with three different conformations of the C6 exocyclic group (tg, gt and gg) as shown in Fig.…”

Section: Introductionmentioning

confidence: 93%

“…4 Top row, relative potential energies of cellotetramers with respect to different torsion angle HO3-O3/C4-H4 when the exocyclic group at C6 taking tg, gt and gg conformations, respectively; Middle row, distances between H4 and HO3 (shown as circle, primary y-axis) and C4 NMR chemical shifts (shown as black dots, secondary y-axis) in relation to torsion angle HO3-O3/C4-H4. ; Bottom row, representative structures of cellulose tetramer of tg conformation at the max d 13 C4 (conformation A), plateau/energy minimum (conformation B), and min d 13 C4 (conformation C) Cellulose (2018) 25:23-36 31 (Park et al 2009), which varied from 77 to 90 ppm. Due to the small size of the model from the previous work, their calculated d 13 C4 varied from 70 to 75 ppm, * 10 ppm lower than the experiment values.…”

Section: Effect Of Adjacent Ho3 Groupmentioning

confidence: 99%

“…Solid-state NMR spectroscopy of cellulose produces doublet d 13 C4 peaks that have been used to estimate the degree of crystallinity of cellulose as well as the number of glucan chains in elementary cellulose microfibrils (Kennedy et al 2007;Newman et al 1994Newman et al , 1996Park et al 2009;Teeäär et al 1987;Wang et al 2015). Two d 13 C4 peaks, centered at * 89 and * 85 ppm, have been assigned to ordered (crystalline) and disordered (amorphous) regions, respectively (Atalla et al 1980;Earl and VanderHart 1980).…”

Section: Introductionmentioning

confidence: 99%

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Structural factors affecting 13C NMR chemical shifts of cellulose: a computational study

et al. 2017

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The doublet C4 peaks at * 85 and * 89 ppm in solid-state 13 C NMR spectra of native cellulose have been attributed to signals of C4 atoms on the surface (solvent-exposed) and in the interior of microfibrils, designated as sC4 and iC4, respectively. The relative intensity ratios of sC4 and iC4 observed in NMR spectra of cellulose have been used to estimate the degree of crystallinity of cellulose and the number of glucan chains in cellulose microfibrils. However, the molecular structures of cellulose responsible for the specific surface and interior C4 peaks have not been positively confirmed. Using density functional theory (DFT) methods and structures produced from classical molecular dynamics simulations, we investigated how the following four factors affect 13 C NMR chemical shifts in cellulose: conformations of exocyclic groups at C6 (tg, gt and gg), H 2 O molecules H-bonded on the surface of the microfibril, glycosidic bond angles (U, W) and the distances between H4 and HO3 atoms. We focus on changes in the d 13 C4 value because it is the most significant observable for the same C atom within the cellulose structure. DFT results indicate that different conformations of the exocyclic groups at C6 have the greatest influence on d 13 C4 peak separation, while the other three factors have secondary effects that increase the spread of the calculated C4 interior and surface peaks.

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Measuring the crystallinity index of cellulose by solid state 13C nuclear magnetic resonance

Cited by 230 publications

References 13 publications

Cellulose I crystallinity determination using FT–Raman spectroscopy: univariate and multivariate methods

Cellulose I crystallinity determination using FT–Raman spectroscopy: univariate and multivariate methods

Structural factors affecting 13C NMR chemical shifts of cellulose: a computational study

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