Biodiesel from Microalgae, Yeast, and Bacteria: Engine Performance and Exhaust Emissions

Wahlen, Bradley D.; Morgan, Michael R. A.; McCurdy, Alex T.; Willis, Robert M.; Morgan, Michael D.; Dye, Daniel J.; Bugbee, Bruce; Wood, Byard D.; Seefeldt, Lance C.

doi:10.1021/ef3012382

Cited by 135 publications

(78 citation statements)

References 51 publications

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“…These results indicate that, due to substantial differences in the specific gravities of the evaluated fuels, one should also consider the energy capacity expressed per volume of fuel when assessing fuel consumption (Lapuerta et al, 2011). The findings of this study relative to fuel consumption are in general agreement with the findings for FAME (Graboski and McCormick, 1998; Wahlen et al, 2013; Kim et al, 2014) and HVORD fuels (Kim et al, 2014). …”

Section: Resultssupporting

confidence: 89%

“…FAME biodiesel fuels are obtained from various plant and algae oils and from animal fats through the process of transesterification (Graboski and McCormick, 1998; Wahlen et al, 2013). The chemical and physical properties of FAME fuels are highly dependent on feedstock: for example, FAME biodiesel produced from soybean oil is primarily made up of unsaturated oleic and linoleic fatty acid while the biodiesel produced from palm oil is primarily made up of saturated palmitic and unsaturated oleic fatty acid.…”

Section: Introductionmentioning

confidence: 99%

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Effects of FAME biodiesel and HVORD on emissions from an older-technology diesel engine

Bugarski¹,

Hummer²,

Vanderslice³

2017

Mining Engineering

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The results of laboratory evaluations were used to compare the potential of two alternative, biomass-derived fuels as a control strategy to reduce the exposure of underground miners to aerosols and gases emitted by diesel-powered equipment. The effects of fatty acid methyl ester (FAME) biodiesel and hydrotreated vegetable oil renewable diesel (HVORD) on criteria aerosol and gaseous emissions from an older-technology, naturally aspirated, mechanically controlled engine equipped with a diesel oxidation catalytic converter were compared with those of widely used petroleum-derived, ultralow-sulfur diesels (ULSDs). The emissions were characterized for four selected steady-state conditions. When fueled with FAME biodiesel and HVORD, the engine emitted less aerosols by total particulate mass, total carbon mass, elemental carbon mass and total number than when it was fueled with ULSDs. Compared with ULSDs, FAME biodiesel and HVORD produced aerosols that were characterized by single modal distributions, smaller count median diameters, and lower total and peak concentrations. For the majority of test cases, FAME biodiesel and HVORD favorably affected nitric oxide (NO) and adversely affected nitrogen dioxide (NO2) generation. Therefore, the use of these alternative fuels appears to be a viable tool for the underground mining industry to address the issues related to emissions from diesel engines, and to transition toward more universal solutions provided by advanced engines with integrated exhaust after treatment technologies.

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Section: Resultssupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Effects of FAME biodiesel and HVORD on emissions from an older-technology diesel engine

Bugarski¹,

Hummer²,

Vanderslice³

2017

Mining Engineering

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“…Biodiesel, derived from oil or fats, is ideal for the heavy transportation and aviation markets. A number of studies showed that microbial lipids prepared from oleaginous yeasts, bacteria, and microalgae could be employed to produce biodiesel of comparable properties with those made from typical plant oils (Liu and Zhao, 2007;Wahlen et al, 2013). Thus, it is currently considered as the potential feedstock for biodiesel (Meng et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Kinetics of continuous cultivation of the oleaginous yeast Rhodosporidium toruloides

Shen

Gong

Yang

et al. 2013

Journal of Biotechnology

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“…The experiments showed that both strains can consume these carbon sources and accumulate lipids close to 20 % of their own weight. With regard to bacterial biodiesel properties and subsequent engine testing, only one analysis has been reported (Wahlen et al 2012). In this study, the bacterium R. opacus was grown in sucrose and biodiesel properties were compared with those from microalgae and yeast oil-based biodiesel.…”

Section: Bacteriamentioning

confidence: 99%

“…Although it varies depending on the species and substrate, it is mostly composed of palmitic and oleic acid, the latter being preferred for the biodiesel industry due to its high unsaturation degree (Pinzi et al 2011). Wahlen et al (2012) compared biodiesel properties, performance, and emissions in a diesel engine, biodiesel being produced from soybean, algae, bacteria, and yeast oil. Only small differences in terms of exhaust emissions were detected, as biodiesel from yeast oil emitted lower hydrocarbon but higher NO x emissions.…”

Section: Yeastmentioning

confidence: 99%

New Frontiers in the Production of Biodiesel: Biodiesel Derived from Macro and Microorganisms

Leiva-Candia

Dorado

2014

Lecture Notes in Energy

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The biodiesel industry is gaining interest in the past years due to the depletion of the easily extracted petroleum, the increasing demand to the automotive market, and the environmental damage. It is acknowledged that the main obstacle to biodiesel marketing is the cost of production, which is mostly due to the price of the raw material (usually vegetable oils). In this way, the goal is to provide low-cost raw materials. This may be achieved by feedstocks that do not require arable land, do not depend on growing seasons, and that give added value to waste, helping also to its recycling. In this way, oleaginous organisms may be considered an alternative feedstock for the biodiesel industry, as they meet all the previous requirements. This chapter presents the state of the art and the main characteristics of the oil and biodiesel provided by macroorganism (insects) and microorganism (bacteria, filamentous fungi, and yeasts).

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Biodiesel from Microalgae, Yeast, and Bacteria: Engine Performance and Exhaust Emissions

Cited by 135 publications

References 51 publications

Effects of FAME biodiesel and HVORD on emissions from an older-technology diesel engine

Effects of FAME biodiesel and HVORD on emissions from an older-technology diesel engine

Kinetics of continuous cultivation of the oleaginous yeast Rhodosporidium toruloides

New Frontiers in the Production of Biodiesel: Biodiesel Derived from Macro and Microorganisms

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