@inproceedings{scholars13376, year = {2020}, publisher = {Institute of Physics Publishing}, journal = {IOP Conference Series: Materials Science and Engineering}, doi = {10.1088/1757-899X/736/2/022018}, number = {2}, volume = {736}, note = {cited By 3; Conference of Energy Security and Chemical Engineering Congress 2019, ESChE 2019 ; Conference Date: 17 July 2019 Through 19 July 2019; Conference Code:158114}, title = {Cultivation of microalgae in fluidized bed bioreactor: Impacts of light intensity and CO2 concentration}, author = {Rosli, S. S. and Lim, J. W. and Lam, M. K. and Ho, Y. C. and Yeong, Y. F. and Mohd Zaid, H. F. and Chew, T. L. and Aljunid Merican, Z. M. and Mohamad, M.}, issn = {17578981}, abstract = {Harvesting of suspended microalgae biomass will generally incur excessive time and intensive energy due to low biomass density. Microalgae cultivation via fluidized bed bioreactor was introduced to tackle the harvesting process in which the support material was fluidizing within the culture medium, allowing the microalgae to settle onto the surface of fluidized material and grow thereafter. The Central Composite Design (CCD) was adopted to design the experiments for optimization of attached microalgae growth onto the fluidized bioreactor. The optimization condition occurred at 216 {\^I}1/4mol/m2 s light intensity and 9 CO2 concentration with maximum biomass concentration (Xmax) and maximum specific growth rate {\^I}1/4max) of attached microalgae obtained at 0.692 g/L and 0.028 1/h, respectively. The Verhulst logistic kinetic model illustrated the attached microalgae growth from lag to stationary phase, supporting the use of this model to represent the kinetic of attached microalgae growth onto the fluidized bed bioreactor under various condition. {\^A}{\copyright} Published under licence by IOP Publishing Ltd.}, url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85081294019&doi=10.1088\%2f1757-899X\%2f736\%2f2\%2f022018&partnerID=40&md5=07f0cc8fd579d2790e2ae1c65ffe748c} }