From sugarcane bagasse

Santos, J.C., Silva, S.S., Mussatto, S.I., Carvalho, W. and Cunha, M.A.A., Immobilized cells cultivated in semi-continuous mode in a fluidized bed reactor for xylitol production from sugarcane bagasse, World. Microbiol. Biotech., 21 (2005) 531-535. [Pg.237]

Values of k varied from l.lOx 10 h to 15.3x 10 h for the oxidation reaction of lignin from sugarcane straw, whereas, for oxidation reactions of lignin from sugarcane bagasse, it varied from 10.07x10 to 56.61 x 10 h . ... [Pg.659]

Activation energy calculated for the oxidation reaction of lignin from sugarcane straw was 34,239 J/mol (R =0.9676 Fig. 3), a value higher than that found in the oxidation reaction of lignin from sugarcane bagasse, which is 2,3378 J/mol (i =0.9721 Fig. 4). [Pg.660]

Spectra in Fig. 5 were obtained by FTIR relative to the experiment performed at 80 °C for lignin from sugarcane bagasse. The peaks at 1,600 and 1,506 cm correspond to the... [Pg.660]

Table 2 Values of rate constants and for the oxidation reaction of lignins from sugarcane bagasse.

Fig. 8 Scores values of PC 1 x PC2 and PC 1 x PC3 from FTIR spectra of samples of lignin from sugarcane bagasse...

D. A. Cerqueira, G. Rodrigues Filho, R. M. N. Assun9ao, Cd. S. Meireles, L. C. Toledo, M. Zeni, K. Mello, and J. Duarte, Characterization of cellulose triacetate membranes, produced from sugarcane bagasse, using PEG 600 as additive, Polym. Bull, 60 (2008) 397-404. [Pg.115]

The body is made of a biodegradable plant fiber based structural material. Fibers or pulp from sugarcane, bagasse can be used. This material is inexpensive and thus decreases production costs. The material provides a solid mechanical support for holding the fluid in the container. [Pg.208]

Dawson L, Boopathy R. (2008). Cellulosic ethanol production from sugarcane bagasse without enzymatic saccharification. BioResources, 3, 452-460. [Pg.25]

Milagres AMF, Santos E, Piovan T, Roberto IC. (2004). Production of xylanases by Ther-momyces aurantiacus from sugarcane bagasse in an aerated growth fermenter. Process Biochem, 39, 1387-1391. [Pg.129]

Borges ER, Pereira N Jr. (2011). Succinic acid production from sugarcane bagasse hemi-ceUulose hydrolysate by Actinobacillus succinogenes. J Ind Microbiol Biotechnol, 38, 1001-1011. [Pg.464]

Preparation of cellulose and lignin from sugarcane bagasse... [Pg.106]

Cellulose and lignin were obtained from sugarcane bagasse by pretreatment of the bagasse with sulfuric acid, delignification and separation of the fractions. [Pg.106]

Chemical Characterization of Lignin Extracted from Sugarcane Bagasse... [Pg.111]

Morphological Characterization for Composites Reinforced with Cellulose and Lignin from Sugarcane Bagasse and Coconut Fibers... [Pg.114]

S.M. Luz J. Del Tio, G.J.M. Rocha, A.R. GoiKjalves, and A.R DelArco. Cellulose and cel-lulignin from sugarcane bagasse reinforced polypropylenecomposites Effect of acetylation on mechanical and thermal properties. Compos. A 39,1362-1369 (2008). [Pg.124]

GriUo Reno ML, Silva Lora EE, Escobar Palacio JC, Venturini OJ, Buchgeister J, Almazan O. A LCA (life cyde assessment) of the methanol production from sugarcane bagasse. Energy 2011 36(6) 3716-26. [Pg.326]

Slavutsky and Bertuzzi (2014) recently showed ceUulose nanociystals (C-NC) obtained from sugarcane bagasse. They formulated starch/C-NC composites and their water barrier properties were studied. The measured film solubility, contact angle, and water sorption isotherm indicated that reinforced starch/C-NC films have a lower affinity to water molecules than starch films. The same effect was observed in studies by Savadekar and Mhaske (2012). They studied the effect of C-NC incorporation on TPS matrix and found that the nanofillers addition improved their barrier and mechanical properties. [Pg.42]

Some functional characteristics of extmded blends of fiber from sugarcane bagasse, whey protein concentrate, and com starch. Cienc Tecnol Aliment 31 870-878... [Pg.69]

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