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The objective of this study was to determine the possibility of using a liquid waste fraction generated in the process of bioethanol production from sugar beets for biomass production from Chlorella vulgaris microalgae. The process of microalgae culture was conducted in three variants differing in the volume of the liquid phase fed to the technological system. The highest technological effects in biomass growth were noted in the experimental variants in which the distillery stillage constituted 5% and 7% of culture medium volume. Concentration of biomass achieved in these variants reached 1416±45.30 mgo.d.m./dm3 and 1458.3±54.52 mgo.d.m./dm3 , respectively. Increasing the content of the liquid waste fraction in the medium to 10% caused significant growth inhibition of biomass of algae from the species Chlorella Vulraris. The use of such a culture medium for microalgae biomass production requires its pre-treatment to remove organic compounds, color and turbidity.
Czasopismo
Rocznik
Tom
Strony
180--194
Opis fizyczny
Bibliogr. 25 poz., rys., tab., wykr.
Twórcy
autor
- University of Warmia and Mazury in Olsztyn Faculty of Environmental Sciences Warszawska street 17, Olsztyn, 10-720, Poland
autor
- University of Warmia and Mazury in Olsztyn Faculty of Environmental Sciences Warszawska street 17, Olsztyn, 10-720, Poland
autor
- University of Warmia and Mazury in Olsztyn Faculty of Environmental Sciences Warszawska street 17, Olsztyn, 10-720, Poland
autor
- University of Warmia and Mazury in Olsztyn Faculty of Environmental Sciences Warszawska street 17, Olsztyn, 10-720, Poland
Bibliografia
- Acuner E., Dilek F.B. (2004), Treatment of tectilon yellow 2G by Chlorella vulgaris, “Process Biochemistry” No. 39, p. 623-631
- Bernal C.B. et al. (2008), Microalgal dynamics in batch reactors for municipal wastewater treatment containing dairy sewage water, “Water, Air, and Soil Pollution” No. 190, p. 259-270
- Börjesson P., Berglund M. (2006), Environmental systems analysis of biogas systems – part I: Fuel-cycle emissions, “Biomass Bioenergy” No. 30(5), p. 469-485
- Essam T. et al. (2007), Solar-based detoxification of phenol and p-nitrophenol by sequential TiO2 photocatalysis and photosynthetically aerated biological treatment, “Water Research” No. 41, p. 1697-1704
- Fargione J. et al. (2008), Land clearing and the biofuel carbon debt, “Science” No. 319, p. 1235-1238
- Goyal H.B., Seal D., Saxena R.C. (2008), Bio-fuels from thermochemical conversion of renewable resources: a review, “Renewable and Sustainable Energy Reviews” No. 12(2), p. 504-517
- Holm-Nielsen J.B., Al Seadib T., Oleskowicz-Popielc P. (2009), The future of anaerobic digestion and biogas utilization, “Bioresource Technology” No. 100(22), p. 5478-5484
- Johansson D., Azar C. (2007), A Scenario based analysis of land competition between food and bioenergy production in the us, “Climatic Change” No. 82(3), p. 267-291
- Li Y. et al. (2008), Biofuels from microalgae, “Biotechnology Progress” No. 24(4), p. 815-820
- Lin L. et al. (2007), Use of ammoniacal nitrogen tolerant microalgae in landfill leachate treatment, “Waste Management” No. 27, p. 1376-1382
- Lundquist T.J. (2008), Production of algae in conjunction with wastewater treatment, in: NREL-AFOSR workshop on algal oil for jet fuel production
- Mùnoz R., Guieysse B. (2006), Algal-bacterial processes for the treatment of hazardous contaminants: a review, “Water Research” No. 40(15), p. 2799-2815
- Mùnoz R. et al. (2003), Salicylate biodegradation by various algal–bacterial consortia under photosynthetic oxygenation, “Biotechnology Letters” No. 25, p. 1905-1911
- Mùnoz R. et al. (2004), Photosynthetically oxygenated salicylate biodegradation in a continuous stirred tank photobioreactor, “Biotechnology and Bioengineering” No. 87(6), p. 797-803
- Ogbonna J.C., Yoshizawa H., Tanaka H. (2000), Treatment of high strength organic wastewater by a mixed culture of photosynthetic microorganisms, “Journal of Applied Phycology” No. 12, p. 277-284
- Rajeshwari K.V. et al. (2000), State-of-the-art of anaerobic digestion technology for industrial wastewater treatment, “Renewable and Sustainable Energy Reviews” No. 4(2), p. 135-156
- Searchinger T. et al. (2008), Use of us croplands for biofuels increases greenhouse gases through emissions from land-use change, “Science” No. 319, p. 1238-1240
- Shen Y. et al. (2009), Microalgae mass production methods, “Transactions of the ASABE” No. 52, p. 1275-1287
- Smith V. et al. (2010), The ecology of algal biodiesel production, “Trends in Ecology and Evolution” No. 25(5), p. 301-309
- Su Y., Mennerich A., Urban B. (2012), Coupled nutrient removal and biomass production with mixed algal culture: impact of biotic and abiotic factors, “Bioresource Technology” No. 118, p. 469-476
- Szwaja S. et al. (2016), Influence of a light source on microalgae growth and subsequent anaerobic digestion of harvested biomass, “Biomass and Bioenergy” No. 91, p. 243-249
- Uggetti E. et al. (2014), Anaerobic digestate as substrate for microalgae culture: The role of ammonium concentration on the microalgae productivity, “Bioresource Technology” No. 152, p. 437-443
- Valderramaa L.T. et al. (2002), Treatment of recalcitrant wastewater from ethanol and citric acid production using the microalga Chlorella vulgaris and the macrophyte Lemna minuscule, “Water Resources” No. 36, p. 4185-4192
- Wang L. et al. (2010), Cultivation of green algae Chlorella sp. in different wastewaters from municipal wastewater treatment plant, “Applied Biochemical Biotechnology” No. 162, p. 1174-1186
- Yewalkar S.N., Dhumal K.N., Sainis J.K. (2007), Chromium (VI)-reducing Chlorella spp. isolated from disposal sites of paper-pulp and electroplating industry, “Journal of Applied Phycology” No. 19, p. 459-46
Typ dokumentu
Bibliografia
Identyfikator YADDA
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