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Zhang, Z., Wong, H.H., Albertson, P.L., Doherty, W.O.S., O’Hara, I.M., 2013. Laboratory
and pilot scale pretreatment of sugarcane bagasse by acidified aqueous glycerol solu-
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Zhao, X.B., Peng, F., Cheng, K., Liu, D.H., 2009. Enhancement of the enzymatic digestibility
of sugarcane bagasse by alkali-peracetic acid pretreatment. Enzyme Microb. Technol.
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Further reading
Beeharry, R.P., 2006. Extended sugarcane biomass utilisation for exportable electricity pro-
duction in mauritius. Biomass Bioenergy 11 (6), 441.
Biotechnology Industry Organization, 2010. Bio-based chemicals and products: a new driver
for green jobs. Available from: ,http://www.bio.org/articles/biobased-chemicals-and-
productsnew-driver-green-jobs. (accessed 14.12.15).
Bomgardner, M.M., 2014. Bio-based polymers. Chem. Eng. News 92, 10 14.
Carvalho, W., Canilha, L., Silva, S.S., 2008. Semi-continuous xylose-to-xylitol bioconversion
by Ca-alginate entrapped yeast cells in a stirred tank reactor. Bioprocess Biosyst. Eng.
31, 493 498.
Energy Research Centre of the Netherlands, 2010. PHYLLIS: The Composition of Biomass
and Waste. Energy Research Centre of the Netherlands.
Franco, H.C.J., Trivelin, P.C.O., Faroni, C.E., Vitti, A.C., Otto, R., 2008. Utilization by sugar
cane of nitrogen applied at planting. Rev. Bras. Cienc. Solo 32, 2763 2770.
¸
Hassuda, S., Reboucas, A.C., Cunha, R.C.A., 1990. Aspectos qualitativos da infiltrac¸a ˜oda
vinhaca de cana no Aquı ´fero Bauru. Revista IG, Sa ˜o Paulo 11 (2), 5 20.
¸
Magalha ˜es, P.S.G., Braunbeck, O.A., 2014. Sugarcane and straw harvesting for ethanol pro-
duction. In: Cortez, L.A.B. (Ed.), Sugarcane Bioethanol—R&D for Productivity and
Sustainability. Editora Edgard Blu ¨cher, Sa ˜o Paulo, pp. 465 476. Available from: http://
dx.doi.org/10.5151/BlucherOA-Sugarcane-SUGARCANEBIOETHANOL_43.
Naspolini, B.F., de Oliveira Machado, A.C., Cravo Junior, W.B., Freire, D.M.G.,
Cammarota, M.C., 2017. Bioconversion of sugarcane vinasse into high-added value pro-
ducts and energy. BioMed Res. Int 1 11. Article ID 8986165.
Prabhakar, N., Raju, D.V.L.N., Vidya Sagar, R., 2010. Cane trash as fuel. In: Proceedings of
International Society of Sugar Cane Technologists, p. 11.
Prakasham, R.S., Rao, R.S., Hobbs, P.J., 2009. Current trends in biotechnological production
of xylitol and future prospects. Curr. Trends Biotechnol. Pharm. 3, 8 36.
Rein, P.W., 2005. The effect of green cane harvesting on a sugar mill. In: Proceedings of
ISSCT, pp. 513 520.
Salomon, K.R., Lora, E.E.S., 2005. Energetic potential estimate for electric energy generation
of different sources of biogas in Brazil. Biomass Bioenergy 2 (1), 7 67.
Salomon, K.R., Lora, E.E.S., 2009. Estimate of the electric energy generating potential for
different sources of biogas in Brazil. Biomass Bioenergy 33, 1101 1107. Available
from: https://doi.org/10.1016/j.biombioe.2009.03.001.
Scarlat, N., Dallemand, J.F., Monforti-Ferrario, F., Nita, V., 2015. The role of biomass and
bioenergy in a future bioeconomy: policies and facts. Environ. Dev. 15, 3 34.
Silveira, M.H.L., Morais, A.R.C., da Costa Lopes, A.M., Olekszyszen, D.N., Bogel-Łukasik,
R., Andreaus, J., et al., 2015. Current pretreatment technologies for the development of
cellulosic ethanol and biorefineries. ChemSusChem. 8 (20), 3366 3390.
