Energy balance and life cycle assessments in producing microalgae biodiesel via a continuous microalgal-bacterial photobioreactor loaded with wastewater

Leong, W.H. and Lim, J.W. and Rawindran, H. and Liew, C.S. and Lam, M.K. and Ho, Y.C. and Khoo, K.S. and Kusakabe, K. and Abdelghani, H.T.M. and Ho, C.-D. and Ng, H.-S. and Usman, A. and Kang, H.-S. (2023) Energy balance and life cycle assessments in producing microalgae biodiesel via a continuous microalgal-bacterial photobioreactor loaded with wastewater. Chemosphere, 341. ISSN 00456535

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Abstract

Life cycle assessments of microalgal cultivation systems are often conducted to evaluate the sustainability and feasibility factors of the entire production chain. Unlike widely reported conventional microalgal cultivation systems, the present work adopted a microalgal-bacterial cultivation approach which was upscaled into a pilot-scale continuous photobioreactor for microalgal biomass production into biodiesel from wastewater resources. A multiple cradle-to-cradle system ranging from microalgal biomass-to-lipid-to-biodiesel was evaluated to provide insights into the energy demand of each processes making up the microalgae-to-biodiesel value chain system. Energy feasibility studies revealed positive NER values (4.95�8.38) for producing microalgal biomass but deficit values for microalgal-to-biodiesel (0.14�0.23), stemming from the high energy input requirements in the downstream processes for converting biomass into lipid and biodiesel accounting to 88�90 of the cumulative energy demand. Although the energy balance for microalgae-to-biodiesel is in the deficits, it is comparable with other reported biodiesel production case studies (0.12�0.40). Nevertheless, the approach to using microalgal-bacterial cultivation system has improved the overall energy efficiency especially in the upstream processes compared to conventional microalgal cultivation systems. Energy life cycle assessments with other microalgal based biofuel systems also proposed effective measures in increasing the energy feasibility either by utilizing the residual biomass and less energy demanding downstream extraction processes from microalgal biomass. The microalgal-bacterial cultivation system is anticipated to offer both environmental and economic prospects for upscaling by effectively exploiting the low-cost nutrients from wastewaters via bioconversion into valuable microalgal biomass and biodiesel. © 2023 Elsevier Ltd

Item Type: Article
Impact Factor: cited By 0
Uncontrolled Keywords: Biodiesel; Biomass; Costs; Energy efficiency; Energy management; Microalgae; Photobioreactors; Sustainable development, Continuous photobioreactor; Energy; Life cycle assessment; Micro-algae; Microalgal biomass; Microalgal cultivations; Microalgal-bacterial; Net energy ratios; Photobiore-actor; Production chain, Life cycle, biodiesel; biofuel; chloroform; lipid; methanol, biofuel; biomass; bioreactor; cultivation; energy balance; energy efficiency; life cycle analysis; sustainability; upscaling; wastewater; wastewater treatment plant, activated sludge; Article; bacterium; biomass; chemical oxygen demand; Chlorella vulgaris; dewatering; electricity; energy balance; energy consumption; harvesting; life cycle; life cycle assessment; light intensity; microalga; nonhuman; nutrient; renewable energy; solvent extraction; transesterification; wastewater
Depositing User: Mr Ahmad Suhairi Mohamed Lazim
Date Deposited: 04 Oct 2023 08:37
Last Modified: 04 Oct 2023 08:37
URI: http://scholars.utp.edu.my/id/eprint/37297

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