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News and Trends
http://biopact.com/2008/02/virgin-in-historic-biofuel-flight.html A Boeing 747 Virgin Atlantic Airways commercial aircraft made its first test flight with one of its unmodified engines powered by a 25% biofuel blend in a separate fuel tank. The biofuel, which was made from coconut and babassu oil feedstocks from Brazil, was blended with standard jet kerosene fuel. The passenger-free test flight took off from London’s Heathrow Airport and landed in Amsterdam, Netherlands. The information obtained from the test flight will be evaluated by the project collaborators, Virgin Atlantic, Boeing, and engine-maker, GE, and may pave the way for “biofuel-powered” commercial flights in the near future. Related information: babbasu plant http://www.dipbot.unict.it/Palms/Descr06.html A joint research cooperation between the Indian Agricultural Research Institute (IARI) and Saskatchewan University (Canada) aims to develop “advanced bioenergy” using biomass crops and feedstocks. The research will focus on the production of four types of biofuels from biomass: biodiesel, bioethanol, biogas, and biohydrogen. The following research areas were identified: (1) ultrasound technology for biodiesel production from jatropha and other oils, (2) biohydrogen production by supercritical gasification technology, (3) acid hydrolysis process for the conversion of biomass into fermentable sugars for ethanol fermentation, and (4) anaerobic digestion of biomass for co-production of biogas and organic fertilizers. Saskatchewan University is known for its “Bioeconomy Centre”, which is envisioned to draw a large numbers of biocience experts in Canada, focusing on bioenergy and bioproducts. The IARI, on the other hand is well known for its high level agricultural research. Related information on supercritical gasification http://www.btgworld.com/technologies/supercritical-gasification.html http://www.carbontrust.co.uk/about/presscentre/080218_Biofuels_Challenge.htm The Carbon Trust is an organization established by the government of the United Kingdom, in response to climate change. It seeks the attainment of a “low carbon economy” by helping companies reduce their carbon emissions and to contribute to the development of “commercial low carbon technologies”. The Carbon Trust recently announced the “Pyrolysis Challenge”, which calls for “Expressions of Interest from potential partners within the scientific community to collaborate in the development of a world-class commercially viable pyrolysis oil upgrading process”. The production of “pyrolysis oil” from the air-free burning (pyrolysis) of “sustainably-sourced biomass” has been identified as a low carbon technology which can produce potentially low-cost biofuels with lesser greenhouse gas emissions. The trust has committed about 5 million pounds (British currency) for “commercially focused research projects” on pyrolysis within a time frame of 3 to 5 years. Among the expected outcomes from research are: “proof of scientific/engineering principle, a novel, low-cost, low GHG intensity pyrolysis technology from biomass, complete characterization of the upgraded oil, an assessment of commercial/environmental value of by-products, and development of a lab-scale or small industrial demonstration unit”. A Pyrolysis Challenge workshop is scheduled on 11 March 2008. Details can be obtained from the Carbon Trust website (URL above).. Energy Crops and Feedstocks for Biofuels Productionhttp://www.biofuelreview.com/content/view/1439/ http://www.timesonline.co.uk/tol/news/uk/science/article3257051.ece A team of scientists from the J. Craig Venter Institute (United States) have successfully assembled the genome (hereditary traits of an organism encoded as a sequence of base pairs in DNA molecules) of a bacterium, Mycoplasma genitalium JCVI-1.0, by artificial means. Although scientists have long been able to make synthetic DNA, they were only successful for DNA chains of short length, having a maximum of about 32 base pairs. The scientific team successfully assembled the genome with a length of 583,000 base pairs. An attempt is being planned to insert the artificial genome into an empty cell and “boot” it up to obtain a living cell that functions on the artificial genome. The technology could reportedly spark applications for “creating new types of microorganisms that could be used in numerous ways, such as green fuels to replace oil and coal, digest toxic waste or absorb greenhouse gases”.. Biofuels Processinghttp://www.energy.gov/news/6015.htm Although the production of cellulosic ethanol (ethanol from cellulosic biomass) is said to have a good net energy yield and a better carbon balance (relative to other bioenergy feedstocks), there are some hurdles to make large scale production cost competitive. One of these hurdles involves the improvement of cost and performance of “cellulases”, the enzymes necessary to degrade the cellulose from the plant biomass into sugars suitable for ethanol fermentation. In an effort to make its cellulosic ethanol production capability competitive by 2012, the United States Department of Energy (US-DOE) announced an investment of $33.8 million within four years, to improve enzyme systems for cellulosic ethanol production. The four projects that have been identified for funding are: (1) “Development of Commercial Enzyme Systems for Lignocellulosic Biomass Saccharification (DSM Innovation Center, Inc), (2) “Enhancing Cellulase Commercial Performance for the Lignocellulosic Biomass Industry” (Genecor), (3) “Development of a Commercial-Ready Enzyme Application System for Ethanol” (Novozymes, Inc), and (4) “Commercialization of Customized Cellulase Solutions for Biomass Saccharification” (Verenium Corporation).. http://www.biofuelreview.com/content/view/1436/ Algae have been identified as one of the potential sources of oil that can be processed into biodiesel. Among the advantages of algae as biodiesel feedstock are its high carbon dioxide fixing (capturing) ability during growth and its not being a “plant-based bioenergy crop”. The conventional method of algal oil production usually involves the cultivation of the algae, harvesting them and extracting the oil by physical or chemical methods. Since the algae are destroyed, cultivation must be redone for the production cycle to continue. A recent article from the Biofuel Review website reports the development of a continuous algal oil extraction strategy without destroying the algae. The proprietary technology, developed by International Energy, Inc, involves growing the algae, stripping off their oils and returning the “oil-stripped” algae into the cultivation tank where they regrow. In the process of regrowth, the algae can accumulate oil again for further stripping. Details of the oil stripping technology, was not mentioned. The advantage of this ”algae recycling” process is the time and cost saved in growing a new set of algae cells. Biomass regeneration time is minimized while enhancing oil yields.. DuPont and BP are two companies that are active in providing energy solutions, and have been one of the first players to venture into the development of butanol as an advanced transport biofuel. As mentioned in many reports, butanol (a four-carbon alcohol) is said to have several advantages as a biofuel compared to ethanol (a two-carbon alcohol) in terms of energy density, fuel economy and anti-corrosion property. A recent press release on the DuPont/BP research partnership reports that an isomeric mixture of biobutanol can maintain high (or better) engine performance, even at blends higher than 10%, which is usually the ceiling blend for ethanol. (An isomeric butanol mixture, contains 1-butanol, 2-butanol and isobutanol, all having four-carbon atoms which differ only in the arrangement of the molecules). According to the report, vehicle testing data showed that a 16% blend of the butanol mixture (with gasoline) “delivers similar fuel performance compared to current 10 percent ethanol blend gasoline fuels, which importantly means that butanol can help achieve higher biofuel penetration without compromising fuel performance”. One of the partnership’s research thrusts is to look into advanced metabolic pathways of the butanol isomers. A full environmental life cycle analysis of the proposed biobutanol process has also been commissioned by DuPont and BP.. Biofuels Policy and Economics
http://www.denmark.dk/en/servicemenu/News/Environment-Energy-Climate-News/HistoricEnergyAgreementSewedUp.htm A new energy policy in Denmark has been put in place aiming for a 20% replacement of its total energy consumption by 2011. Climate and Energy Minister, Connie Hedegaard, said, "With its new energy agreement, Denmark takes the (global) lead in terms of offensive efforts". The achievement of the renewable energy target requires an investment of about US $497 million. Biomass is an important renewable energy resource in Denmark, comprising about 70% of renewable energy consumption. Under the new agreement, better subsidies for biomass energy development are being eyed.. http://biopact.com/2008/02/biofuels-part-of-brazils-major-anti.html The Biopact site reports that Brazil has unveiled an anti-poverty initiative aimed at providing jobs, electricity and infrastructure to the country’s rural poor. Realizing the role of biofuels for rural development and poverty alleviation, biofuel related programs are included in the initiative. The production of biodiesel by small farmers, for example, is being promoted, under measures aimed at socially sustainable agricultural production. Under the Pro Biodiesel program, biodiesel producers can obtain a certificate (a “Social Fuel Stamp”) if they source their feedstock from small farmers, which entitles them to incentives. Rural households which grow the biodiesel feedstocks (such as Jatropha or castor) are also guaranteed a minimum price for the sale of their produce. The program is said to be benefiting about “65,000 of Brazil's poorest farmers in the country's semi-arid Nordeste region”.. |
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