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Biofuels Volume 9, 2018 - Issue 2: Biorefinery for fuels and platform chemicals
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Articles

Energy analysis of extractive-transesterification of algal lipids for biocrude production

Edith Martinez-GuerraCivil and Environmental Engineering Department, Mississippi State University, Mississippi State, MS 39762Correspondence[email protected]
ORCID Iconhttp://orcid.org/0000-0002-7689-3736View further author information
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Veera Gnaneswar GudeCivil and Environmental Engineering Department, Mississippi State University, Mississippi State, MS 39762Correspondence[email protected]
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Pages 139-146 | Received 30 Dec 2015, Accepted 04 Mar 2016, Published online: 28 Jun 2016
 
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ABSTRACT

Algae biomass is the most promising feedstock for biofuel production since it can provide a sustainable route to achieve independence from fossil fuel sources. Energy-positive biofuel production from algal biomass has been the major goal for many researchers in recent years. The search for efficient extraction and chemical conversion methods that produce high energy ratios has become an important endeavor in this field. In this regard, microwaves and ultrasound have been utilized as convenient mechanisms in algal biodiesel production. However, none of the studies reported on the energy analysis of the extraction and transesterification methods. Energy analysis of the extractive-transesterification processes using microwave (with ethanol and with ethanol and hexane as co-solvent) and ultrasound irradiations to produce biocrude from microalgae (Chlorella sp.) is presented in this paper. Power input and reaction volumes were varied to study the effects of power density and intensity on the biocrude yields. Results from this analysis show that a biocrude yield higher than 90% could be obtained with an energy input to output ratio of less than one when microwave irradiation is used as the heating mechanism.

Acknowledgments

This research was supported in part by the United States Environmental Protection Agency (USEPA). This research was also supported by the Office of Research and Economic Development (ORED), the Bagley College of Engineering (BCoE), and the Department of Civil and Environmental Engineering (CEE) at Mississippi State University. The authors would like to thank Mrs. Marta Amirsadeghi and Dr. Todd French of the Swalm School of Chemical Engineering for their help with GC-MS analysis.

Disclosure statement

No potential conflict of interest was reported by the authors.

Additional information

Funding

US Environmental Protection Agency [grant number SU835519].

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