References
- 1. MORONEY, J. V., YNALVEZ, R. A. I. 2009. Algal Photosynthesis. Chichester: eLS. John Wiley & Sons Ltd. Available on: http://www.els.net/WileyCDA/ElsArticle/refId-a0000322.html
- 2. RASHID, N. et al. 2014. Current status, issues and developments in microalgae derived biodiesel production. Renewable and Sustainable Energy Reviews, Vol. 40, p.760–778.
- 3. DAHIYA, A. 2014. In Bioenergy: Biomass to Biofuel. 1.st edition. pp. 219-238.
- 4. AL-LWAYZY, S. H. et al. 2014. Biofuels from the fresh water microalgae chlorella vulgaris (FWM-CV) for diesel engines. Energies, 7(3), p. 1829–1851.
- 5. SCARSELLA, M. et al. 2010. Study on the optimal growing of Chlorella vulgaris in bubble colum photobiorectors. Chemical Engineering Transactions, Vol. 20.
- 6. GUIRY, M. D. 2015. AlgaeBase. World-wide electronic publication. National University of Ireland, Galway. Available on: http://www.algaebase.org; searched on 20 January 2015.
- 7. NAUTIYAL, P. et al. 2014. Production and characterization of biodiesel from algae. Fuel Processing Technology, 120(04), pp.79–88.
- 8. FISHMAN, D. et al. U.S. DOE 2010. National Algal Biofuels Technology Roadmap. . U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, Biomass Program. [online] 05/2015 [cit. 2015-03-02]. Available on: <http://www1.eere.energy.gov/bioenergy/pdfs/algal_biofuels_roadmap.pdf>
- 9. LAVENS, P., SORGELOOS, P. (eds.) Manual on the production and use of live food for aquaculture FAO Fisheries Technical Paper. No. 361. Rome, FAO.[online] 1996, 295 p., ISBN 92-5-103934-8. [cit. 2015-02-01]. Available on: <ftp://ftp.fao.org/docrep/fao/003/w3732e/w3732e00.pdf>
- 10. HARUN, I. et al. 2014. Effects of Natural Light Dilution on Microalgae Growth. International Journal of Chemical Engineering and Applications, 5(2), pp.112–116.
- 11. AL-QASMI, M. et al. 2012. A Review of Effect of Light on Microalgae Growth. Proceedings of the World Congress on Engineering, I(07), pp. 8–10.
- 12. BLAIR, M.F. et al. 2014. Light and growth medium effect on Chlorella vulgaris biomass production. Journal of Environmental Chemical Engineering, 2(1), pp. 665–674.
- 13. BARSANTI, L. et al. Algae: Anatomy, Biochemistry, and Biotechnology. [online] Second Edition. ISBN 978-1-4398-6733-4. [cit. 2015-12-02]. Available from: <https://books.google.sk/books?id=uazMBQAAQBAJ&printsec=frontcover&hl=sk#v=onepage&q&f=false>
- 14. UGWU, C. U., AOYAGI, H. 2012. Microalgal Culture Systems: An Insight into their Designs, Operation and Applications. Biotechnology,11(3), pp. 127–132.
- 15. UGWU, C. U. et al. 2008. Photobioreactors for mass cultivation of algae. Bioresource Technology, 99(10), pp. 4021–4028.
- 16. SINGH, R. N., SHARMA, S. 2012. Development of suitable photobioreactor for algae production - A review. Renewable and Sustainable Energy Reviews, 16(4), pp. 2347–2353.
- 17. POSTEN, C. 2009. Design principles of photo-bioreactors for cultivation of microalgae. Engineering in Life Sciences, 9(3), pp.165–177.
- 18. CHINNASAMY, S. et al. Biomass production potential of a wastewater alga chlorella vulgaris ARC 1 under elevated levels of CO2 and temperature. International Journal of Molecular Sciences, 10(2), pp. 518–532.
- 19. CONVERTI, A. et al. 2009. Effect of temperature and nitrogen concentration on the growth and lipid content of Nannochloropsis oculata and Chlorella vulgaris for biodiesel production. Chemical Engineering and Processing: Process Intensification, Vol. 48, pp. 1146–1151.
- 20. MAYO, A. W. 1997. Effects of temperature and pH on the kinetic growth of unialga Chlorella vulgaris cultures containing bacteria. Water Environment Research, 69(1), pp. 64–72.
- 21. CASSIDY, K. O. Evaluating algal growthat different temperatures. 2011. Theses and Dissertations-Biosystems and Agricultural Engineering. Paper 3. [cit. 2015-10-02]. Available from: <http://uknowledge.uky.edu/bae_etds/3>
- 22. BARGHBANI, R. 2012. Investigating the Effects of Several Parameters on the Growth of Chlorella vulgaris Using Taguchi’s Experimental Approach. International Journal of Biotechnology for Wellness Industries,Vol. 1, pp.128–133.
- 23. YAN, C. et al. 2013. Effects of various LED light wavelengths and intensities on the performance of purifying synthetic domestic sewage by microalgae at different influent C/N ratios. Ecological Engineering, Vol. 51, pp. 24–32.
- 24. HULTBERG, M. et al. 2014. Impact of light quality on biomass production and fatty acid content in the microalga Chlorella vulgaris. Bioresource technology, Vol. 159, pp. 465–467.
- 25. FU, W. et al. 2012. Maximizing biomass productivity and cell density of Chlorella vulgaris by using light-emitting diode-based photobioreactor. Journal of biotechnology, 161(3), pp. 242–249.
- 26. MOHSENPOUR, S. F. et al. 2012. Spectral conversion of light for enhanced microalgae growth rates and photosynthetic pigment production. Bioresource technology, Vol. 125, pp. 75–81.
- 27. RYU, H. J. et al. 2009. Optimization of the influential factors for the improvement of CO2utilization efficiency and CO2 mass transfer rate. Journal of Industrial and Engineering Chemistry, 15(4), pp. 471–475.
- 28. GUO, Z. et al. Control of CO2 input conditions during outdoor culture of Chlorella vulgaris in bubble column photobioreactors. Bioresource Technology, Vol. 186, pp. 238–245.
- 29. MAEDA, K. et al. 1995. CO2 fixation from the flue gas on coal-fired thermal power plant by microalgae. Energy Conversion and Management, 36(6-9), pp. 717–720.
- 30. SUNG, K. D. et al. 1999. CO2 fixation by Chlorella sp. KR-1 and its cultural characteristics. Bioresource Technology, Vol. 68, pp. 269–273.
- 31. RENDÓN, S. M. et al. 2013. Effect of Carbon Dioxide Concentration on the Growth Response of Chlorella vulgaris Under Four Different Led Illumination. International Journal of Biotechnology for Wellness Industries, Vol. 2, pp. 125–131.
- 32. CHIU, S.Y. et al. 2011. Microalgal biomass production and on-site bioremediation of carbon dioxide, nitrogen oxide and sulfur dioxide from flue gas using Chlorella sp. cultures. Bioresource technology, Vol. 102, pp. 9135–9142.
- 33. VAIČIULYTĖ, S. et al. 2014. Batch Growth of Chlorella Vulgaris CCALA 896 versus Semi-Continuous Regimen for Enhancing Oil-Rich Biomass Productivity. Energies, 7(6), 2014, pp. 3840–3857.
- 34. YEH, K. L., CHANG, J. S. 2012. Effects of cultivation conditions and media composition on cell growth and lipid productivity of indigenous microalga Chlorella vulgaris ESP-31. Bioresource technology, Vol. 105, pp. 120–127.
- 35. SOSTARIC, M. et al. 2009. Studies on the Growth of Chlorella vulgaris in Culture Media with Different Carbon Sources. Chemical Biochemical Engineering Quarterly, Vol. 23(4), pp. 471–477.
- 36. CROFCHECK, C. et al. 2013. Influence of media composition on the growth rate of Chlorella vulgaris and Scenedesmus acutus utilized for CO2 mitigation. Journal of Biochemical Technology, 4(2), pp. 589–594.