 |
|
Recent News |
Archives |
Tags |
About |
Newsletter |
Submit News |
Links |
 Subscribe
|
|---|
|
New Source for Biofuels Discovered by Researchers (4/24/2008)
Along with cellulose, the cyanobacteria developed by Professor R. Malcolm Brown Jr. and Dr. David Nobles Jr. secrete glucose and sucrose. These simple sugars are the major sources used to produce ethanol. "The cyanobacterium is potentially a very inexpensive source for sugars to use for ethanol and designer fuels," says Nobles, a research associate in the Section of Molecular Genetics and Microbiology. Brown and Nobles say their cyanobacteria can be grown in production facilities on non-agricultural lands using salty water unsuitable for human consumption or crops. Other key findings include:
They recently published their research in the journal Cellulose. Nobles made the new cyanobacteria (also known as blue-green algae) by giving them a set of cellulose-making genes from a non-photosynthetic "vinegar" bacterium, Acetobacter xylinum, well known as a prolific cellulose producer. The new cyanobacteria produce a relatively pure, gel-like form of cellulose that can be broken down easily into glucose. "The problem with cellulose harvested from plants is that it's difficult to break down because it's highly crystalline and mixed with lignins [for structure] and other compounds," Nobles says.
"The huge expense in making cellulosic ethanol and biofuels is in using enzymes and mechanical methods to break cellulose down," says Nobles. "Using the cyanobacteria escapes these expensive processes." Sources being used or considered for ethanol production in the United States include switchgrass and wood (cellulose), corn (glucose) and sugarcane (sucrose). True algae are also being developed for biodiesel production. Brown sees a major benefit in using cyanobacteria to produce ethanol is a reduction in the amount of arable land turned over to fuel production and decreased pressure on forests. "The pressure is on all these corn farmers to produce corn for non-food sources," says Brown, the Johnson & Johnson Centennial Chair in Plant Cell Biology. "That same demand, for sucrose, is now being put on Brazil to open up more of the Amazon rainforest to produce more sugarcane for our growing energy needs. We don't want to do that. You'll never get the forests back." Brown and Nobles calculate that the approximate area needed to produce ethanol with corn to fuel all U.S. transportation needs is around 820,000 square miles, an area almost the size of the entire Midwest. They hypothesize they could produce an equal amount of ethanol using an area half that size with the cyanobacteria based on current levels of productivity in the lab, but they caution that there is a lot of work ahead before cyanobacteria can provide such fuel in the field. Work with laboratory scale photobioreactors has shown the potential for a 17-fold increase in productivity. If this can be achieved in the field and on a large scale, only 3.5 percent of the area growing corn could be used for cyanobacterial biofuels. Cyanobacteria are just one of many potential solutions for renewable energy, says Brown. "There will be many avenues to become completely energy independent, and we want to be part of the overall effort," Brown says. "Petroleum is a precious commodity. We should be using it to make useful products, not just burning it and turning it into carbon dioxide." Brown and Nobles are now researching the best methods to scale up efficient and cost-effective production of cyanobacteria. Two patent applications, 20080085520 and 20080085536, were recently published in the United States Patent and Trade Office. Note: This story has been adapted from a news release issued by The University of Texas at Austin Post Comments: |
|
| Archives | Submit News | Advertise With Us | Contact Us | Links |
|---|
|
|
Tiny water creepy crawlies from South Korea and the Russian Far East
NASA satellite data helps pinpoint glaciers' role in sea level rise
Weather on the outer planets only goes so deep
Shattering the endurance record for small electric UAV
But what does it do?
Sea level influenced tropical climate during the last ice age
World's smallest droplets
Using clay to grow bone
Grammar errors? The brain detects them even when you are unaware
Principles of locomotion in confined spaces could help robot teams work underground
Researchers perform fastest measurements ever made of ion channel proteins
Ultraresponsive magnetic nanoscavengers for next generation water purification
Do potatoes grow on vines? A review of the wild relatives of some favorite food plants
New discovery of ancient diet shatters conventional ideas of how agriculture emerged
Carnivorous plant throws out 'junk' DNA
Untangling the tree of life
More effective, cheaper concrete manufactured with ash from olive residue biomass
Seahorse's armor gives engineers insight into robotics designs
New quantitative analysis for open source software projects
High-volume Bitcoin exchanges less likely to fail, but more likely breached, says study
Computer scientists develop video game that teaches how to program in Java
Do palm trees hold the key to immortality?
Researchers show how we can do math problems unconsciously
Keep moving and have fun
New strategy for fingerprint visualization developed at Hebrew University
Children's bicycle helmets shown to be effective in impact and crush tests
How Usain Bolt can run faster -- effortlessly
Enhancing cognition in older adults also changes personality
Add boron for better batteries
Artificial forest for solar water-splitting
Beautiful 'flowers' self-assemble in a beaker
The molecular basis of strawberry aroma
Solar panels as inexpensive as paint? It's possible due to research at UB, elsewhere
New technique to improve quality control of lithium-ion batteries
A giant leap to commercialization of polymer solar cell
Microwave oven cooks up solar cell material