Environmental Engineering Reference
In-Depth Information
Chinnasamy S, Bhatnagar A, Hunt RW, Das KC (2010)
Microalgae cultivation in a wastewater dominated by
carpet mill effluents for biofuel applications. Biore-
sour Technol 101:3097-3105
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CD, Chang JS, Lin CS (2011) Microalgal biomass
production and on-site bioremediation of carbon
dioxide, nitrogen oxide and sulfur dioxide from flue
gas using Chlorella sp. cultures. Bioresour Technol
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Coca M, Barrocal VM, Lucas S, Gonz£lez-Benito G, Gar-
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2014
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Stress induction of zeaxanthin formation in the
ʲ-Carotene accumulating alga Dunaliella salina Teod.
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Draaisma RB, Wijffels RH, Slegers PM, Brentner LB,
Roy A, Barbosa MJ (2013) Food commodities from
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Ekman A, B￶rjesson P (2011) Environmental assess-
ment of propionic acid produced in an agricultural
biomass-based biorefinery system. J Cleaner Prod
19:1257-1265
Ermakova S, Men'shova R, Vishchuk O, Kim SM, Um
BH, Isakov V, Zvyagintseva T (2013) Water-soluble
polysaccharides from the brown alga Eisenia bicyclis :
structural characteristics and antitumor activity. Algal
Res 2:51-58
Fahd S, Fiorentino G, Mellino S, Ulgiati S (2012) Crop-
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the added value of the biorefinery concept. Energy
37:79-93
Faulkner DJ (2001) Marine natural products. Nat Prod
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Ferreira AF, Ribeiro LA, Batistam AP, Marquesm PASS,
Nobrem BP, Palavram AMF, da Silva PP, Gouveiam
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Fornell R, Berntsson T, ᅤsblad A (2013) Techno-eco-
nomic analysis of a kraft pulp-mill-based biorefinery
producing both ethanol and dimethyl ether. Energy
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perspective: the global blue and green water foot-
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22:764-775
Goh CS, Lee KT (2010) A visionary and conceptual
macroalgae-based third-generation bioethanol (TGB)
with the biofuel production. Microalgal carbo-
hydrate, protein, lipid, and pigments can be used
in pharmaceutical, nutraceutical, food and feed
industries with various applications. High energy
demand for biofuels production can be reduced
by producing valuable coproduct. Utilization of
wastewater as a nutrient source and flue gases as a
source of CO 2 for microalgal cultivation reduces
the environmental concerns as well as improves
carbon and WF. Biorefinary approach of micro-
algal biofuel production thus becomes imperative
for sustainable application. Thus, practicing this
approach could make biofuels production from
microalgae sustainable, economically viable, and
environmentally friendly.
References
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