Non-woody Biomass as Sources of Nanocellulose Particles: A Review of Extraction Procedures

Owonubi, Shesan John; Agwuncha, Stephen C.; Malima, Nyemaga Masanje; Shombe, Ginena Bildard; Makhatha, Mamookho Elizabeth; Revaprasadu, Neerish

doi:10.3389/fenrg.2021.608825

Cited by 39 publications

(18 citation statements)

References 133 publications

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“…In contrast, the lignin content of sugarcane leaves observed in this study was 6.39% which was lower than wood material (25%) [41]. Other published work supports this conclusion, and there are similar reports for the lignin derived from nonwoody fibers such as banana fiber, soy hull, pineapple leaf, sisal leaf, abaca leaf, and curaua leaf ranged between 4.9 and 7.7% [42]. .00-28.30%, respectively, while the contents in the same order of dry-torrefied samples at the temperature range 225-300 °C were in the ranges of 23.99-48.30, 0.66-36.65, and 8.25-60.18%, respectively.…”

Section: Chemical Composition Of Raw and Torrefied Sugarcane Leavessupporting

confidence: 73%

Comparative study of solid biofuels derived from sugarcane leaves with two different thermochemical conversion methods: wet and dry torrefaction

2021

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This work describes the conversion of sugarcane leaves into biocoal with two thermal processes: wet torrefaction (subcritical water, 175-250 °C) and dry torrefaction (nitrogen atmosphere, 225-300 °C). The residence time was 30 min for both processes. The effects on physical and energy characteristics, including mass and energy yield, proximate and ultimate analyses, fiber analysis, higher heating value (HHV), structural parameters determined by Fourier-transform infrared spectroscopy, and O/C and H/C atomic ratios were used for comparisons. The results showed that increasing the reaction temperature lowers the mass yield; however, it also significantly improves the fuel ratio of torrefied samples. The highest HHV of wet and drytorrefied samples were 23.31 and 22.07 MJ/kg, respectively. The best removal of ash and sulfur content was obtained under wet torrefaction. Moreover, wet torrefaction was recommended as a suitable process for hemicellulose depolymerization. At 250 °C, the wet-torrefied sample had the highest fuel ratio (0.48) and was suited for biomass co-firing. The finding that wet-torrefied samples reached the same range of lignite at lower reaction temperatures than dry-torrefied samples was particularly intriguing. Torrefaction at the temperatures below 250 °C did not prove to have a statistically significant effect on the energy properties of the dry-torrefied samples. Therefore, wet torrefaction is a promising process in the thermochemical conversion of sugarcane leaves into solid biofuel.

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Section: Chemical Composition Of Raw and Torrefied Sugarcane Leavessupporting

confidence: 73%

Comparative study of solid biofuels derived from sugarcane leaves with two different thermochemical conversion methods: wet and dry torrefaction

2021

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“…The yield decreased with time increment than 20 min, therefore, the optimum yield value for obtaining cellulose from NaClO/GNFC was 95% which is higher compared to the cellulose yield of NaOH/GNFC of the previous publications which was 89% of pineapple [ 41 ], 83.40% of blenched fiber [ 42 ], 67.40% for non-woody biomass constitutes [ 34 ], 85.40% for non-woody biomass constitutes, 54.30% for organo-solvent miscanthus pulp (OMP) [ 31 ], and 81.00% and 54.00% from flax fibers and cotton linters [ 29 ]. Moreover, the yield of NaClO/H 2 SO 4 cellulose was 90.00% the yield of the previous investigators which was 82% for non-woody biomass constitutes [ 43 ], ranging between 55 and 60% for bleached kraft pulp of loblolly pinewood [ 44 ], 85.75% for filter paper [ 6 ], 83.60% for native cellulosic feedstock [ 45 ] ( Apendix A ), 84.00% for oil palm ( Elaeisguineensis ) empty fruit bunch [ 46 ], from flax fibers (81.00%) and 54% from flax fibers (81.00%) and cotton linters [ 14 ]. In addition, Figure 3 a,b show that the temperature increment had a higher effect on the yield decrement compared to the reaction time [ 9 ].…”

Section: Resultsmentioning

confidence: 86%

An Innovative Preparation, Characterization, and Optimization of Nanocellulose Fibers (NCF) Using Ultrasonic Waves

Alanazi

2022

Polymers

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Recently, environmental and ecological concerns have become a major issue owing to the shortage of resources, high cost, and so forth. In my research, I present an innovative, environmentally friendly, and economical way to prepare nanocellulose from grass wastes with a sodium hypochlorite (NaClO) solution of different concentrations (1–6% mol) at different times 10–80 min, washed with distilled water, and treated with ultrasonic waves. The optimum yield of the isolated cellulose was 95%, 90%, and 87% NaClO at 25 °C for 20 min and with NaOH and H2SO4 at 25 °C with 5% M, respectively. The obtained samples were characterized by dynamic light scattering (DLS), Fourier-transform infrared (FT-IR) spectroscopy, and X-ray diffraction (XRD). The effect of test temperature and reaction times on the crystallinity index (IC) of GNFC with different treated mediums was carried out and investigated. The IC was analyzed using the diffraction pattern and computed according to the Segal empirical method (method A), and the sum of the area under the crystalline adjusted peaks (method B) and their values proved that the effect of temperature is prominent. In both methods, GNFC/H2SO4 had the highest value followed by GNFC/NaOH, GNFC/NaClO and real sample nano fiber cellulose (RSNFC). The infrared spectral features showed no distinct changes of the four cellulose specimens at different conditions. The particle size distribution data proved that low acid concentration hydrolysis was not sufficient to obtain nano-sized cellulose particles. The Zeta potential was higher in accordance with (GNFC/H2SO4 > GNFC/NaOH > GNFC/NaClO), indicating the acid higher effect.

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“…On the other hand, the cellulose present in wood has a structure with lignin and hemicellulose intertwined, and β-glucose is linked in a linear structure with cis-shaped chains connected by high-density hydrogen bonds. Therefore, β-glucose chain is a polymeric material that is difficult to process [8].…”

Section: Introductionmentioning

confidence: 99%

Reaction Mechanisms Applied to Starch Modification for Biodegradable Plastics: Etherification and Esterification

Kim

Jung

2022

International Journal of Polymer Science

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Although many studies are being actively conducted to develop biodegradable plastic materials, most of these reports focused more on efficiency or performance improvement than on the reaction mechanism. This paper discussed the reaction mechanism applied to starch modification by etherification and esterification, which are the most studied in the field of biodegradable plastics. In the starch-reforming reaction by etherification, the effects of the reaction temperature, pH, solvent, and by-products on the chemical structure and physical properties of biodegradable plastics were discussed. In esterification, the structure of the substituents and the reaction solvents were examined. As a material that can replace plastics, the aim is to help derive new ideas on the design of reaction condition that can expand the use of starch.

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Non-woody Biomass as Sources of Nanocellulose Particles: A Review of Extraction Procedures

Cited by 39 publications

References 133 publications

Comparative study of solid biofuels derived from sugarcane leaves with two different thermochemical conversion methods: wet and dry torrefaction

Comparative study of solid biofuels derived from sugarcane leaves with two different thermochemical conversion methods: wet and dry torrefaction

An Innovative Preparation, Characterization, and Optimization of Nanocellulose Fibers (NCF) Using Ultrasonic Waves

Reaction Mechanisms Applied to Starch Modification for Biodegradable Plastics: Etherification and Esterification

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