A high-energy biofuel — potentially capable of replacing or supplementing expensive missile fuels, such as JP10 — has been created via the use of a genetically engineered bacterium by researchers at the Georgia Institute of Technology and the Joint BioEnergy Institute.
For those wondering, the hydrocarbon in question, pinene, is actually exactly what it sounds like, a chemical produced by trees (especially pine trees). Kind of funny when you think about it — rockets powered by a chemical used by trees to repel insects produced by bacteria genetically engineered by humans. :/
Georgia Tech researchers examine the production of the hydrocarbon pinene in a series of laboratory test tubes. Shown are (l-r) Pamela Peralta-Yahya, an assistant professor in the School of Chemistry and Biochemistry and the School of Chemical and Biomolecular Engineering, and Stephen Sarria, a graduate student in the School of Chemistry and Biochemistry.
Image Credit: Georgia Tech Photo, Rob Felt
Improvements to the process are still necessary in order for it to become economically viable (production boosted 26-fold), but given the great value placed on high-energy fuels by governments/militaries/etc, it’s very likely that we’ll hear more about this in the relatively near future.
The researchers also note the interesting fact that the biofuel could potentially help “facilitate (the) development of a new generation of more powerful engines.” Hmmm…
The Georgia Institute of Technology provides more:
By inserting enzymes from trees into the bacterium, first author and Georgia Tech graduate student Stephen Sarria, working under the guidance of assistant professor Pamela Peralta-Yahya, boosted pinene production six-fold over earlier bioengineering efforts. Though a more dramatic improvement will be needed before pinene dimers can compete with petroleum-based JP-10, the scientists believe they have identified the major obstacles that must be overcome to reach that goal.
“We have made a sustainable precursor to a tactical fuel with a high energy density,” stated Peralta-Yahya, an assistant professor in the School of Chemistry and Biochemistry and the School of Chemical and Biomolecular Engineering at Georgia Tech. “We are concentrating on making a ‘drop-in’ fuel that looks just like what is being produced from petroleum and can fit into existing distribution systems.”
Given the fact that JP-10 is itself a very limited fuel — only so much can be extracted from any single barrel of oil — the potential for it to be replaced by a (relatively) expensive biofuel is much greater than it is for something like gasoline. JP-10 currently sells for around $25 per gallon.
“If you are trying to make an alternative to gasoline, you are competing against $3 per gallon,” Peralta-Yahya continued. “That requires a long optimization process. Our process will be competitive with $25 per gallon in a much shorter time.”
More information on the research process:
Peralta-Yahya and collaborators set out to improve on previous efforts by studying alternative enzymes that could be inserted into the E. coli bacterium. They settled on two classes of enzymes — three pinene synthases (PS) and three geranyl diphosphate synthases (GPPS) — and experimented to see which combinations produced the best results.
Their results were much better than earlier efforts, but the researchers were puzzled because for a different hydrocarbon, similar enzymes produced more fuel per liter. So they tried an additional step to improve their efficiency. They placed the two enzymes adjacent to one another in the E. coli cells, ensuring that molecules produced by one enzyme would immediately contact the other. That boosted their production to 32 milligrams per liter — much better than earlier efforts, but still not competitive with petroleum-based JP-10. Peralta-Yahya believes the problem now lies with built-in process inhibitions that will be more challenging to address.
“We found that the enzyme was being inhibited by the substrate, and that the inhibition was concentration-dependent,” she explained. “Now we need either an enzyme that is not inhibited at high substrate concentrations, or we need a pathway that is able to maintain low substrate concentrations throughout the run. Both of these are difficult, but not insurmountable, problems.”
“Even though we are still in the milligrams per liter level, because the product we are trying to make is so much more expensive than diesel or gasoline means that we are relatively closer.”
The new findings were published in the journal ACS Synthetic Biology.
High-Energy Biofuel For Rockets, Missiles, And Other Aerospace Applications, Via Engineered Bacteria was originally published on CleanTechnica. To read more from CleanTechnica, join over 50,000 other subscribers: Google+ | Email | Facebook | RSS | Twitter.
2013 was a classic good news-bad news year for renewable energy with surging solar, green building, and EVs counterbalanced by slowing wind and investment
2013: Renewable Energy’s Best of Times, Worst of Times was originally published on CleanTechnica.
To read more from CleanTechnica, join over 50,000 other subscribers: Google+ | Email | Facebook | RSS | Twitter.
Originally Published in the ECOreport.
The biofuel industry has been enjoying a 19.6% annual growth since 2005. That is about to change. The World’s 53.2 billion gallon biofuel industry could grow to over 60 billion gallons during the next few years. Much of this will come from riskier next generation technologies.
Approximately 65.9% of global biofuel capacity in 2013 was ethanol, and this should increase slightly over the next few years.
Biodiesel shall continue to be the worlds’ second largest biofuel, and capacity should reach around 18.6 billion gallons a year by 2017.
The strongest growth will be in products like non-food diesel, butanol, biojet, and biocrude, which should increase at a rate of about 18.7% a year and control 3.3% of the market by 2017.
“Next-generation feedstocks like waste oils and cellulosic biomass are not tied up in the food supply and could unlock significant economic advantages, assuming novel conversions commercialize,” said Andrew Soare, Lux Research Senior Analyst and the lead author of the report titled, “Emerging Feedstocks and Fuels Spark Biofuel Capacity Expansion through 2017.”
“Meanwhile, next-generation fuels like renewable diesel will break down current barriers and drive long-term biofuel capacity expansion,” he added.
“Of the 782 MGY of announced cellulosic ethanol capacity, we expect 384 MGY to come to fruition, led by companies such as Beta Renewables, POET-DSM, and Abengoa,” the report states. “Renewable diesel from waste will emerge as a key biofuel process, while butanol and biocrude producers have the flexibility to sell into the chemicals market, and their effect on overall biofuel capacity remains minor.”
Close to 80% of the renewable diesel capacity over the next few years is already online, with players like Neste Oil and Diamond Green Diesel leading the market.
Gevo owns the only existent butanol facility and that is expected to come online soon.
AltAir has signed a 15 million gallon biojet contract with United Airlines. While this amount is relatively insignificant, it could signal the beginning of a shift in the industry.
Algal biofuels, such as Sapphire Energy’s much talked about green crude, are still years away from making a significant contribution to the market.
Americas’ biofuel industry enjoys high utilization and significant export, but is still threatened by regulatory instability.
There should be considerable growth in Europe, which has a 10% blending target for 2020, and in China. Non-food biofuels could meet China’s energy needs.
Lux Research analysts compiled a database of over 1,700 biofuel production facilities in 82 countries for this study
The report, “Emerging Feedstocks and Fuels Spark Biofuel Capacity Expansion through 2017,” is part of the Lux Research Alternative Fuels Intelligence service.
The Non-Food Biofuel Sector Should Grow Significantly, Lux Reports was originally published on CleanTechnica. To read more from CleanTechnica, join over 50,000 other subscribers: Google+ | Email | Facebook | RSS | Twitter.
I wrote last week that we should probably cover the link between food and broader issues a little more here on Eat Drink Better. With a nudge from our site director, Becky Striepe, and network founder/publisher, David Anderson, I’ve decided to cover the complicated but important topic of rising food prices today.
The LA Times had a decent piece on this topic recently that included a number of interesting food statistics. What of the following did you know?