Martin Tango scite author profile

Due to the concern on the availability of recoverable fossil fuel reserves and the environmental problems caused by the use those fossil fuels, considerable attention has been given to biodiesel production as an alternative to petrodiesel. However, as the biodiesel is produced from vegetable oils and animal fats, there are concerns that biodiesel feedstock may compete with food supply in the long-term. Hence, the recent focus is to find oil bearing plants that produce non-edible oils as the feedstock for biodiesel production. In this paper, two plant species, soapnut (Sapindus mukorossi) and jatropha (jatropha curcas, L.) are discussed as newer sources of oil for biodiesel production. Experimental analysis showed that both oils have great potential to be used as feedstock for biodiesel production. Fatty acid methyl ester (FAME) from cold pressed soapnut seed oil was envisaged as biodiesel source for the first time. Soapnut oil was found to have average of 9.1% free FA, 84.43% triglycerides, 4.88% sterol and 1.59% others. Jatropha oil contains approximately 14% free FA, approximately 5% higher than soapnut oil. Soapnut oil biodiesel contains approximately 85% unsaturated FA while jatropha oil biodiesel was found to have approximately 80% unsaturated FA. Oleic acid was found to be the dominant FA in both soapnut and jatropha biodiesel. Over 97% conversion to FAME was achieved for both soapnut and jatropha oil.

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Impact of ozonation on water quality in marine recirculation systems

Tango

Gagnon

2003

Aquacultural Engineering

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Effect of temperature on lactic acid production from cheese whey using Lactobacillus helveticus under batch conditions

Tango

1999

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Potential of Extremophiles for Biotechnological and Petroleum Applications

Tango¹,

Islam²

2002

Energy Sources

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The ability of microorganisms to survive under harsh conditions has recently prompted researchers to study these microbes to better understand their characteristics and eventually utilize them in various applications. Extremophilic microorganisms withstand one or more extreme condition constraints due to cold, heat, high acidity, high alkalinity, high salinity, and high pressure levels. These constraints would destroy normal microorganisms. Extremophiles can be classi ed according to the environment in which they survive. Many extremophilic microorganisms possess properties suitable for biotechnological and commercial uses. This article discusses the characteristics and future potentials of extremophiles.

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Martin Tango

Non-Edible Plant Oils as New Sources for Biodiesel Production

Impact of ozonation on water quality in marine recirculation systems

Effect of temperature on lactic acid production from cheese whey using Lactobacillus helveticus under batch conditions

Potential of Extremophiles for Biotechnological and Petroleum Applications

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