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Extreme makeover chemistry style
June 17, 2009In revisiting a chemical reaction that's been in the literature for several decades and adding a new wrinkle of their own, researchers with Berkeley Lab and the University of California (UC) Berkeley have discovered a mild and relatively inexpensive procedure for removing oxygen from biomass. This procedure, if it can be effectively industrialized, could allow many of today's petrochemical products, including plastics, to instead be made from biomass.
"We've found and optimized a selective, one-pot deoxygenation technique based on a formic acid treatment," said Robert Bergman, a co-principal investigator on this project who holds a joint appointment with Berkeley Lab's Chemical Sciences Division and the UC Berkeley Chemistry Department.
The formic acid, Bergman said, converts glycerol, a major and unwanted by-product in the manufacturing of biodiesel, into allyl alcohol, which is used as a starting material in the manufacturing of polymers, drugs, organic compounds, herbicides, pesticides and other chemical products. Allyl alcohol today is produced from the oxidation of petroleum.
Said Jonathan Ellman, a UC Berkeley chemistry professor and the other principal investigator in this research, "Right now, about five percent of the world's supply of petroleum is used to make feedstocks that are synthesized into commodity chemicals. If these feedstocks can instead be made from biomass they become renewable and their production will no longer be a detriment to the environment."
Biomass has been drawing wide public attention for its potential to be converted into carbon-neutral biofuels, but there is also huge potential for it to be converted into chemical feedstocks. It is safe to say that a day does not go by without each of us making use of multiple petrochemical products. Feedstocks for such products obtained from biomass rather than petroleum would be renewable as well as biodegradable. However, unlike petrochemical feedstocks, which are made by adding oxygen to petroleum, biomass feedstocks require the removal of oxygen from the raw material.
Bergman and Ellman, working with Elena Arceo, a Fulbright scholar from Spain, and Peter Marsden, a UC Berkely graduate student, used labeling experiments and a unique distillation system to take a new look at an old chemical reaction in which formic acid, the chemical found in bee venom, was used to remove oxygen from glycerol. In its original conception, the reaction was low-yielding, primarily because of substantial charring, an unselective combustion that leads to an intractable mixture under high heat. Bergman and Ellman found that simply protecting this reaction from air provided a much improved process for the deoxygenation of glycerol.
Said Bergman, "Treating glycerol with formic acid while directing a stream of nitrogen through the reaction mixture completely eliminates charring. Besides protecting the product from atmospheric oxidation, the nitrogen also facilitates distillation of the alcohol. The final product shows substantially improved yield (80-percent) and higher selectivity."
Said Ellman, "From our studies we also gained a much better understanding of the basic chemistry behind the reaction. We thought that the charring was a random oxidation process because the reaction had been carried out in air and we expected that running it in a nitrogen environment would improve things. However, in studying the basic chemistry we uncovered an unexpected reaction pathway that really broadens the generality of this reaction and expands its potential applications."
With this new reaction pathway, the formic acid-mediated deoxygenation technique developed by Bergman and Ellman could be used to convert the carbohydrates in biomass, as well as other polyhdroxy compounds, into the chemical feedstocks, such as olefins (alkenes) that are now derived from petroleum. The technique could also prove useful in the process by which biomass is converted into liquid transportation fuels.
Said Bergman, "Our preliminary results with inexpensive biomass-derived polyols suggest that the reaction of polyhydroxy compounds with formic acid will be a valuable alternative for the manufacture of reduced oxygen content products. However, scaling this technique up so that biomass feedstocks are competitive with feedstocks derived from petroleum is going to be an engineering challenge."
Added Ellman, "Scaling the technique up to industrial levels is probably going to require the combined efforts of industrial and academic laboratories, but if we are able to one day make commodity chemicals as well as fuels from biomass, we can protect the atmosphere from further damage and at the same time help lower current carbon dioxide levels."
DOE/Lawrence Berkeley National Laboratory
Said Jonathan Ellman, a UC Berkeley chemistry professor and the other principal investigator in this research, "Right now, about five percent of the world's supply of petroleum is used to make feedstocks that are synthesized into commodity chemicals. If these feedstocks can instead be made from biomass they become renewable and their production will no longer be a detriment to the environment."
Biomass has been drawing wide public attention for its potential to be converted into carbon-neutral biofuels, but there is also huge potential for it to be converted into chemical feedstocks. It is safe to say that a day does not go by without each of us making use of multiple petrochemical products. Feedstocks for such products obtained from biomass rather than petroleum would be renewable as well as biodegradable. However, unlike petrochemical feedstocks, which are made by adding oxygen to petroleum, biomass feedstocks require the removal of oxygen from the raw material.
Bergman and Ellman, working with Elena Arceo, a Fulbright scholar from Spain, and Peter Marsden, a UC Berkely graduate student, used labeling experiments and a unique distillation system to take a new look at an old chemical reaction in which formic acid, the chemical found in bee venom, was used to remove oxygen from glycerol. In its original conception, the reaction was low-yielding, primarily because of substantial charring, an unselective combustion that leads to an intractable mixture under high heat. Bergman and Ellman found that simply protecting this reaction from air provided a much improved process for the deoxygenation of glycerol.
Said Bergman, "Treating glycerol with formic acid while directing a stream of nitrogen through the reaction mixture completely eliminates charring. Besides protecting the product from atmospheric oxidation, the nitrogen also facilitates distillation of the alcohol. The final product shows substantially improved yield (80-percent) and higher selectivity."
Said Ellman, "From our studies we also gained a much better understanding of the basic chemistry behind the reaction. We thought that the charring was a random oxidation process because the reaction had been carried out in air and we expected that running it in a nitrogen environment would improve things. However, in studying the basic chemistry we uncovered an unexpected reaction pathway that really broadens the generality of this reaction and expands its potential applications."
With this new reaction pathway, the formic acid-mediated deoxygenation technique developed by Bergman and Ellman could be used to convert the carbohydrates in biomass, as well as other polyhdroxy compounds, into the chemical feedstocks, such as olefins (alkenes) that are now derived from petroleum. The technique could also prove useful in the process by which biomass is converted into liquid transportation fuels.
Said Bergman, "Our preliminary results with inexpensive biomass-derived polyols suggest that the reaction of polyhydroxy compounds with formic acid will be a valuable alternative for the manufacture of reduced oxygen content products. However, scaling this technique up so that biomass feedstocks are competitive with feedstocks derived from petroleum is going to be an engineering challenge."
Added Ellman, "Scaling the technique up to industrial levels is probably going to require the combined efforts of industrial and academic laboratories, but if we are able to one day make commodity chemicals as well as fuels from biomass, we can protect the atmosphere from further damage and at the same time help lower current carbon dioxide levels."
DOE/Lawrence Berkeley National Laboratory
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Popping the cork on biofuel agriculture
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Report examines hidden costs of energy production and use
A new report from the National Research Council examines and, when possible, estimates "hidden" costs of energy production and use -- such as the damage air pollution imposes on human health -- that are not reflected in market prices of coal, oil, other energy sources, or the electricity and gasoline produced from them.
Caltech researchers reveal unexpected sources of nitrogen fixation
Researchers at the California Institute of Technology (Caltech) have identified an unexpected metabolic ability within a symbiotic community of microorganisms that may help solve a lingering mystery about the world's nitrogen-cycling budget.
Tech researchers using nanotechnology in biofuel process to save money, environment
Dr. James Palmer, associate professor of chemical engineering at Louisiana Tech University, is collaborating with fellow professors Dr. Yuri Lvov, Dr. Dale Snow, and Dr. Hisham Hegab to capitalize on the environmental and financial benefits of "biofuels" by using nanotechnology to further improve the cellulosic ethanol processes.
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