Tag Archives: green
Next-Generation Biofuels Are Inching Towards Reality, Gallon by Gallon
Advanced biofuels have been on the cusp of commercialization for years, but high prices and technological challenges have held them back. Is that starting to change? By Bryan Walsh @bryanrwalshOct. 11, 2013 Photo courtesy Novozymes Novozymes’ new plant in Italy is the world’s first advanced biofuels facility Whatever happened to next-generation biofuels? Made from sources like corn stalks or what straw that don’t compete with food, unlike current biofuels, next-generation biofuels were going to be greener and more efficient than corn-based ethanol, which is still the dominant source of biofuel in the U.S. When Congress passed the 2007 energy bill, it expected the country to be producing over 1 billion gallons of next-generation biofuels by 2013. But the advanced biofuel industry has developed far more slowly than lawmakers predicted, leading the Environmental Protection Agency (EPA) to cut the 2013 mandae for cellulosic biofuels to just 4 million gallons—and even that target could be difficult to meet, given that only 142,000 gallons are available now. It’s not that companies don’t know how to make cellulosic ethanol or biofuel from algae. It’s that they’ve struggled to do so cheaply and at a scale large enough to compete with oil. “The technology just hasn’t matured yet,” says Peder Holk Nielsen, the CEO of the Danish biotech company Novozymes, which has been involved in next-generation biofuel research and development for years. “It’s simply been too expensive.” But if the race to create workable next-generation biofuels has slowed, it’s far from over—and there may still be a few surprises. First Novozymes, which has been developing enzymes for industrial use since the 1920s. Earlier this week Novozymes, in partnership with the Italian biofuels company Beta Renewables, announced the opening of the world’s largest advanced biofuels facility. Built in northern Italy, the plant is the first in the world to be designed and built to produce bioethanol from agricultural residues and energy crops at a commercial scale. The facility will produce over 20 million gallons of cellulosic ethanol a year. “This plant was built with the purpose of demonstrating that the technology is possible,” says Nielsen. “Once we’ve built it, we can optimize it.” Cellulosic ethanol has been difficult to produce for the same reason that it’s impossible for the human stomach to digest cellulose, the material that makes up the tough cell walls of green plants. It takes specialized enzymes to break down cellulose into simple plant sugars, which can then be converted into fuel. (Humans lack those stomach enzymes, unlike cows, which is what allows them to digest grass.) Novozymes’ role is providing the industrial enzymes needed to break down the tough wheat straw, rice straw and arundo donax—a high-yielding energy crop grown on marginal land—that the Italian plant will be using. Those enzymes aren’t cheap—Nielsen notes that while the enzymes used to make corn ethanol cost 3 to 7 cents per gallons, those used for cellulosic ethanol run 30 to 40 cents a gallon. Bringing down the cost of those enzymes will be key to making cellulosic ethanol more than just a lab experiment. “We’re convinced that over time, it will be cheaper than gasoline,” says Nielsen. Novozymes isn’t the only company opening up a cellulosic ethanol facility. In 2014 plants from the ethanol company POET, Dupont and the Spanish firm Abengoa will begin producing next-generation ethanol, and the startup KiOR is already running a commercial plant in Mississippi that turns woody biomass into drop-in fuel. Still, next-generation biofuels companies will face daunting technological and market challenges, as a recent Economist article pointed out: Some observers doubt whether even the most sophisticated biofuels can compete with fossil fuels in the near future. Daniel Klein-Marcuschamer, a researcher at the Australian Institute for Bioengineering and Nanotechnology, conducted a comprehensive analysis of renewable aviation fuels. He concluded that producing first-generation bio-jet fuel from sugarcane would require oil prices of at least $168 a barrel to be competitive, and that some second-generation algae technologies would require crude oil to soar above $1,000 a barrel (the current price is around $110) to break even. Mr Klein-Marcuschamer has made his model open-source in an effort to help the industry find ways to make biofuels more competitive. Even if second-generation processes can be economically scaled up, however, that might in turn highlight a further problem. To make a significant dent in the 2,500m litres of conventional oil that American refineries churn through each day, biofuel factories would have to be able to get hold of a staggering quantity of feedstock. That’s one reason why some next-generation biofuel startups have looked to find new markets for their technology. California-based Solazyme uses custom-built algae to develop better biofuels, and it has sold thousands of gallons of its product to the Navy for use in its ships. But while the company has a 30 million gallon facility in Brazil that should be producing algal biofuel by the end of the year, Solazyme has also branched into making oils for higher profit products like cosmetics, food and petrochemicals. “We view ourselves as a company that makes and tailors oils,” says Jonathan Wolfson, Solazyme’s CEO. “We don’t define ourselves as only a biofuels company.” To that end, late last month Solazyme announced a deal to supply roughly 3 million gallons of algae-produced oil to the consumer products giant Unilever over the next 12 to 18 months, beginning at the start of next year. Unilever has said it will only use sustainable agricultural raw materials by 2020, and Solazyme’s algal oils fit perfectly into that strategy. “We follow the technology in Silicon Valley,” says Wolfson. “We didn’t know what the technology was capable of, and now we can tailor oils we never would have envisioned.” Next-generation biofuels still face an uphill battle—and one where uncertain government policy remains a decisive force. Biofuels that are cheap—and don’t compete with food—could still play a major role in helping the world reduce the carbon footprint of transportation. But as smart companies like Solazyme and Novozymes show, biofuels could just be the beginning for this technology. Read more: http://science.time…./#ixzz2ht6emRoS Continue reading
Cool Planet Announces Launch of Cool Terra™ Biochar Soil Amendment
Reduces Atmospheric CO2 and Increases Crop Yields Field trial opportunities available through the Cool Planet biochar team October 15, 2013 08:00 AM Eastern Daylight Time GREENWOOD VILLAGE, Co. & AMHERST, Mass.–(EON: Enhanced Online News)–Cool Planet Energy Systems, a developer of small-scale bio refineries for the conversion of non-food biomass into biofuels and soil enhancing biochar, announced today the launch of their biochar soil amendment product “Cool Terra™” for commercial agricultural trials. Rick Wilson, Vice President of the Cool Planet Biochar Group, made the announcement at the 2013 US Biochar conference. Cool Planet has assembled one of the top biochar research teams in the world to develop and produce high-performance biochar soil amendments designed for specific applications. The company plans to continue expanding application opportunities with selected partners in the agricultural community leading to commercial product release in 2014. “We are excited about the opportunity to combine science with the real life practical experience of our agriculture industry partners to progress the use of biochar. This work will allow our Carbon Negative fuel technology to improve crop production while delivering environmental benefits” . “We are excited about the opportunity to combine science with the real life practical experience of our agriculture industry partners to progress the use of biochar. This work will allow our Carbon Negative fuel technology to improve crop production while delivering environmental benefits,” said Cool Planet CEO Howard Janzen. Cool Planet, a sponsor of the 2013 North American Biochar Symposium, will discuss the potential impact of the market-driven application of biochar in decarbonizing the atmosphere at the conference being held in Amherst, MA Oct 13 – 16. Cool Planet has shown yield improvements consistently averaging 60% and input reductions of 40%, combined with accelerated growth rates, in commercial field trials in California, enabling cost-effective farming in regions with structured drought such as California and Arizona. “We are already in commercial trials with our proprietary Cool Terra™ biochar soil amendment, and with this launch we plan to add new partners that will lead to large-scale commercialization,” said Rick Wilson of Cool Planet. “We are also making experimental quantities of our activated biochar available through our website.” About Cool Planet Cool Planet is deploying disruptive technology through capital efficient, small scale biorefineries, to economically convert non-food biomass into high-octane, drop-in biofuels. The process also generates value through biochar production, which can be returned to the soil, with the “Cool Terra™ product enabling fertilizer and water retention for increased crop productivity, and more robust plant health. The process can be carbon negative, removing over 100 percent of the carbon footprint for every gallon used, reversing the consequences of fossil fuels. Cool Planet’s technology has a broad portfolio of pending and granted patents. Global investors include BP, Google Ventures, Energy Technology Ventures (GE, ConocoPhillips, NRG Energy), and the Constellation division of Exelon. Connect with Cool Planet on Facebook at facebook.com/CoolPlanetEnergySystems, on Twitter at twitter.com/CoolPlanetFuels and at www.coolplanet.com. Contacts Cool Planet Energy Systems Mike Rocke, +1-940-584-0490 mr@coolplanet.com or Commercial Biochar Sales +1-888-564-9332 biochar@coolplanet.com Continue reading
UCLA Develops Metabolic Pathway To Convert Sugars Into Biofuels
By University of California, Los Angeles | October 04, 2013 Colonies of E. coli genetically modified with the new pathway. University of California, Los Angeles . . . University of California, Los Angeles chemical engineering researchers have created a new synthetic metabolic pathway for breaking down glucose that could lead to a 50 percent increase in the production of biofuels. The new pathway is intended to replace the natural metabolic pathway known as glycolysis, a series of chemical reactions that nearly all organisms use to convert sugars into the molecular precursors that cells need. Glycolysis converts four of the six carbon atoms found in glucose into two-carbon molecules known acetyl-CoA, a precursor to biofuels like ethanol and butanol, as well as fatty acids, amino acids and pharmaceuticals. However, the two remaining glucose carbons are lost as carbon dioxide. Glycolysis is currently used in biorefinies to convert sugars derived from plant biomass into biofuels, but the loss of two carbon atoms for every six that are input is seen as a major gap in the efficiency of the process. The UCLA research team’s synthetic glycolytic pathway converts all six glucose carbon atoms into three molecules of acetyl-CoA without losing any as carbon dioxide. The research is published online Sept. 29 in the peer-reviewed journal Nature. The principal investigator on the research is James Liao, UCLA’s Ralph M. Parsons Foundation Professor of Chemical Engineering and chair of the chemical and biomolecular engineering department. Igor Bogorad, a graduate student in Liao’s laboratory, is the lead author. “This pathway solved one of the most significant limitations in biofuel production and biorefining: losing one-third of carbon from carbohydrate raw materials,” Liao said. “This limitation was previously thought to be insurmountable because of the way glycolysis evolved.” This synthetic pathway uses enzymes found in several distinct pathways in nature. The team first tested and confirmed that the new pathway worked in vitro. Then, they genetically engineered E. coli bacteria to use the synthetic pathway and demonstrated complete carbon conservation. The resulting acetyl-CoA molecules can be used to produce a desired chemical with higher carbon efficiency. The researchers dubbed their new hybrid pathway non-oxidative glycolysis, or NOG. “This is a fundamentally new cycle,” Bogorad said. “We rerouted the most central metabolic pathway and found a way to increase the production of acetyl-CoA. Instead of losing carbon atoms to CO2, you can now conserve them and improve your yields and produce even more product.” The researchers also noted that this new synthetic pathway could be used with many kinds of sugars, which in each case have different numbers of carbon atoms per molecule, and no carbon would be wasted. “For biorefining, a 50 percent improvement in yield would be a huge increase,” Bogorad said. “NOG can be a nice platform with different sugars for a 100 percent conversion to acetyl-CoA. We envision that NOG will have wide-reaching applications and will open up many new possibilities because of the way we can conserve carbon.” The researchers also suggest this new pathway could be used in biofuel production using photosynthetic microbes. The paper’s other author is Tzu-Shyang Lin, who recently received a bachelor’s degree from UCLA in chemical engineering. Continue reading