How To Build A Quick-Charging Electric Battery

How To Build A Quick-Charging Electric Battery 

No one promised that going green would be easy. Just look at the up and down story of technology innovator Altair Nanotechnologies.

Altair makes a nano-particle compound used by Boeing to coat the wings of its stealth fighters and by paint maker Sherwin-Williams to make pigments with fewer toxic residues. But Altair has grander plans: It aims to make batteries that can power an electric car for 150 miles and recharge in the same amount of time it takes to fill up a gas tank and grab a Big Gulp.

The technology seems to be getting close to practical application. Phoenix Motorcars, a Rancho Cucamonga, Calif.-based electric vehicle start-up, plans this year to start selling a small electric pickup truck with drive batteries based in part on the Altair technology. That said, precisely how many Phoenix will buy isn't clear. (Phoenix reported in November that it was scaling back its plans to purchase at least $16 million of batteries from Altair.)

Altair's designers say that the key advantage of their battery is that it can in principle be recharged in an unprecedented 10 minutes. Making this a reality, however, depends on building out a network of high-voltage charging stations. That may be easy for one of Phoenix Motor's first customers, namely Pacific, Gas & Electric. PG&E owns its grid. Others, however, may find setting up the logistics for recharging stations more daunting.

Still, enthusiasm is high within Altair, which raised $40 million from Dubai investment company Al Yousuf in November, even as Altair reported operating losses of $17 million for the first nine months of 2007.

Altair has staked its future on 40-nanometer-size particles of lithium and titanium. It uses the particles to make a coating that covers a battery's anode, an aluminum bar that carries electricity to and from the vehicle's motor. By contrast, most hybrid cars, including Toyota's Prius, use a graphite coating, in conjunction with nickel metal hydride or lithium ion batteries.

The difference is material: When a battery operates or recharges, ions pass through the coating of the anode. Graphite isn't very porous, so the ions literally deform the material as they force their way through.

"This builds up stress and over time the graphite cracks, leading to high resistance and short life," says Altair Chief Executive Alan Gotcher. Altair's nano-titanate coating, by contrast, has a large surface area. That means fewer ions try to force their way through at any given point, lowering resistance and minimizing damage.

By bypassing the graphite design, Altair also avoids dangerous overheating--or thermal runaway-–that can plague large lithium ion batteries. Thermal runaway became a buzzword in 2006 when a Dell laptop computer spontaneously caught fire in a Japan office, an event captured on videotape and instantly shared via YouTube.

Gotcher says his nano-titanate battery lasts for 20,000 full recharge cycles. That's about 20 years, four times the life span of a comparable NIMH or lithium ion battery.

Altair started out as a materials research lab of mining giant BHP Billiton. In 1998, during a downturn in the mining industry, BHP sold the lab to Altair, at the time a shell company.

Tim Spitler, a former DuPont chemical engineer in that lab, spent the next four years learning how to use lithium-titanate to improve batteries. He and his colleagues devised a method to heat treat, mill and spray the material, which looks like a fine white powder, onto the bare aluminum anodes. That gave Altair a way to use lithium-titanate on a commercial scale. But the work didn't dovetail with plans by bigger companies, and the project was shelved.

When Gotcher joined Altair in 2004 he figured the company had a shot at making batteries fully in house. He raised $3.5 million in a secondary stock offering and hired a team engineers to build a working product. Last year Altair made 130 tons of raw lithium-titanate powder at the old BHP lab in Reno. It assembles 35-kilowatt batteries for the likes of Phoenix Motorcars at its factory in Anderson, Ind.

Then there's the challenge of where to get the big dose of power to recharge the batteries.

Phoenix recharges its electric truck battery in 10 minutes with a 440-volt charger--four times the amount of energy in a home wall socket. Scaling that operation, however, would be a challenge: Existing electric grids couldn't easily handle the power drain of rapidly recharging millions of such electric batteries.

So in early January Altair also built its first pair of industrial 1-megawatt batteries--each about the size of a freight car--designed to store excess electricity produced at night. The Virginia power utility AES plans to use the mega-batteries to warehouse power for use during peak consumption times.

Such batteries could help Altair offer 10-minute recharges to the masses. Futuristic filling stations might feature massive batteries below ground, replacing the gasoline storage tanks of today.

Without such infrastructure, going green will certainly take more time. “Five-hour charges would be the fastest possible for residential drivers,” admits Bryon Bliss of Phoenix Motorcars.

Monkey Think, Robot Do

Monkey Think, Robot Do

A rhesus monkey uses thought to make a robot walk, paving the way for paralysis victims to move using brain-powered prosthetic limbs

 
MONKEY BUSINESS: Duke neuroscientist Miguel A. L. Nicolelis and his colleagues is to pave the way for real-time direct interfaces between the brain and electronic and mechanical devices that could be used to restore sensory and motor functions lost through injury or disease.

In a major step toward helping victims of paralysis walk again, researchers at Duke University Medical Center today announced that they had proved monkeys can use their brainpower to control the walking patterns of robots.

The Duke researchers, working with the Computational Brain Project of the Japan Science and Technology Agency, implanted Idoya, a rhesus monkey, with electrodes that gathered signals from her brain's motor and sensory cortex cells as she ambled along on a specially built child-size treadmill. The electrodes recorded the cells' responses as the monkey walked on the treadmill at different speeds; simultaneously, sensors on Idoya's legs tracked their patterns of movement. The information was transmitted in real time from their lab in Durham, N.C., to control the commands of a five-foot-tall humanoid robot (see video here) in Kyoto, Japan.

"We can read signals from cortical areas…the motor and sensory areas of the brain that are involved in the generation of the motor program to walk," says Duke neuroscientist Miguel A. L. Nicolelis. "And we are able to read these signals, decode them, and send them to a device…a bipedal robot that actually starts walking like a monkey."

Through the electrodes implanted in Idoya's brain, researchers found that certain neurons in several regions fire at different phases and frequencies, depending on their role in the complex, multimuscle motor process. During the experiment, the robot continued to move for several minutes after Idoya stopped strolling on her treadmill, indicating that her neural impulses were controlling the metal man's limbs. "She was certainly thinking about the same thing as when she was walking," Nicolelis says. "If she was thinking about grasping bananas, we wouldn't get the same patterns."

The goal of Nicolelis and his colleagues is to pave the way for real-time direct interfaces between a brain and electronic and mechanical devices that could be used to restore sensory and motor functions lost through injury or disease. "Our hope is that one day soon," Nicolelis and his former postdoctoral fellow Sidarta Ribeiro wrote in a December 2006 Scientific American article entitled "Seeking the Neural Code," "we will also master sufficient syntax to talk back to the brain, which would allow us, for example, to build a human prosthetic arm laden with sensors to send tactile feedback into the somatosensory cortex of its user."

The experiment in monkey-to-robotic motion culminates years of studying the primate brain's ability to stimulate robotic arms via neural signals. In 2000 Nicolelis and his colleagues described how they had reliably translated the raw electrical brain activity of an owl monkey named Belle into signals that successfully directed the actions of robotic arms based both at Duke and at a Massachusetts Institute of Technology lab 600 miles (965 kilometers) away in Cambridge, Mass. Belle's tiny hand moved a joystick left or right to correspond with a horizontal series of lights on a display panel in a Duke lab; both robot arms followed suit.

A few years later, in 2005, Nicolelis and his team listened in on brain signals generated by a rhesus monkey named Aurora using a joystick to play a video game and translated them into commands for a mechanical arm to duplicate the motions. Aurora was ultimately able to move a robotic arm sans the joystick, using only her thoughts, an experiment that Nicolelis says addressed "fundamental questions about how brain circuits operate."

 

Apple Unveils Green Ultrathin Laptop

Apple Unveils Green Ultrathin Laptop

Company says new MacBook Air is made from brominated flame retardant–free material and PVC-free internal cables

 
GREEN MACHINE: Apple says the new MacBook Air is made from "brominated flame retardant–free material for the majority of circuit boards as well as PVC-free internal cables."

Apple today debuted its new très trim MacBook Air that is not only thin enough to slip inside a manila envelope but was made without many of the environmentally harmful chemical compounds used in older PCs.

Environmental activist organization Greenpeace just months ago criticized Apple for using bromine—whose vapors are toxic when inhaled—in its hugely popular iPhone. But the company now appears to be making good on its earlier promise that all new products would be free from brominated flame retardants (BFRs) and polyvinyl chloride (PVC), a chlorinated plastic, by the end of this year. Apple says the new MacBook Air is made from "brominated flame retardant–free material for the majority of circuit boards as well as PVC-free internal cables."

The three-pound (1.36-kilogram) laptop, which Apple calls "the world's thinnest" and expects to sell starting at $1,799, also has a recyclable aluminum enclosure and Apple's first mercury-free LCD display with arsenic-free glass. MacBook Air measures 0.16 inch (0.41 centimeter) at its slimmest point and 0.76 inch (1.93 centimeters) at its thickest.

Greenpeace is generally satisfied with the message that the new MacBook sends about cutting back on the environmentally unfriendly materials used to build PCs, but the conservation activists believe Apple can do even better. "We can say that Apple is getting greener, but it's still not green enough," says Zeina Alhajj, coordinator of the organization's international e-waste campaign. Although the new laptop contains less PVC and BFRs, "it could have been made without them entirely, and that would have made Apple an ecological leader." Still, she acknowledges, Apple CEO Steve Jobs emphasized the environment during his Macworld keynote today, "and that's a good start."

The company's bid to eliminate or reduce its use of environmentally harmful chemicals is an encouraging sign that they are trying to keep last year's promise. "I think Apple's extremely serious about improving their environmental footprint, but it takes time to find the new materials to replace what they're currently using," says Shannon Cross, an analyst with technology research firm Cross Research based in Livingston, N.J.

Apple says the 13.3-inch (33.8-centimeter) MacBook Air, which begins shipping at the end of the month, consumes the least amount of power of any Mac, and its retail box, made primarily from post-consumer recycled material, is 56 percent smaller by volume than the previously smallest MacBook packaging. Users will be able to get up to five hours of uninterrupted computing time from a fully charged battery. The laptop is available with either a 1.6 gigahertz or 1.8 gigahertz Intel Core 2 Duo processor with four megabytes of L2 cache. Standard features include two gigabytes of memory and an 80-gigabyte, 1.8-inch (4.6-centimeter) hard drive as well as 802.11n Wi-Fi technology and Bluetooth 2.1.

 

The company today also introduced a number of complementary features, including a compact external storage drive, the ability to wirelessly rent movies from its iTunes store and a wireless file backup called Time Capsule.

Monkey’s Thoughts Propel Robot, a Step That May Help Humans

Monkey’s Thoughts Propel Robot, a Step That May Help Humans

 
THE PLAYERS Dr. Miguel A. L. Nicolelis, left, at Duke University, and Gordon Cheng in Kyoto, Japan, with the robot.

If Idoya could talk, she would have plenty to boast about.

On Thursday, the 12-pound, 32-inch monkey made a 200-pound, 5-foot humanoid robot walk on a treadmill using only her brain activity.

She was in North Carolina, and the robot was in Japan.

It was the first time that brain signals had been used to make a robot walk, said Dr. Miguel A. L. Nicolelis, a neuroscientist at Duke University whose laboratory designed and carried out the experiment.

In 2003, Dr. Nicolelis’s team proved that monkeys could use their thoughts alone to control a robotic arm for reaching and grasping.

These experiments, Dr. Nicolelis said, are the first steps toward a brain machine interface that might permit paralyzed people to walk by directing devices with their thoughts. Electrodes in the person’s brain would send signals to a device worn on the hip, like a cell phone or pager, that would relay those signals to a pair of braces, a kind of external skeleton, worn on the legs.

“When that person thinks about walking,” he said, “walking happens.”

Richard A. Andersen, an expert on such systems at the California Institute of Technology in Pasadena who was not involved in the experiment, said that it was “an important advance to achieve locomotion with a brain machine interface.”

Another expert, Nicho Hatsopoulos, a professor at the University of Chicago, said that the experiment was “an exciting development. And the use of an exoskeleton could be quite fruitful.”

A brain machine interface is any system that allows people or animals to use their brain activity to control an external device. But until ways are found to safely implant electrodes into human brains, most research will remain focused on animals.

In preparing for the experiment, Idoya was trained to walk upright on a treadmill. She held onto a bar with her hands and got treats — raisins and Cheerios — as she walked at different speeds, forward and backward, for 15 minutes a day, 3 days a week, for 2 months.

Meanwhile, electrodes implanted in the so-called leg area of Idoya’s brain recorded the activity of 250 to 300 neurons that fired while she walked. Some neurons became active when her ankle, knee and hip joints moved. Others responded when her feet touched the ground. And some fired in anticipation of her movements.

To obtain a detailed model of Idoya’s leg movements, the researchers also painted her ankle, knee and hip joints with fluorescent stage makeup and, using a special high speed camera, captured her movements on video.

The video and brain cell activity were then combined and translated into a format that a computer could read. This format is able to predict with 90 percent accuracy all permutations of Idoya’s leg movements three to four seconds before the movement takes place.

On Thursday, an alert and ready-to-work Idoya stepped onto her treadmill and began walking at a steady pace with electrodes implanted in her brain. Her walking pattern and brain signals were collected, fed into the computer and transmitted over a high-speed Internet link to a robot in Kyoto, Japan.

The robot, called CB for Computational Brain, has the same range of motion as a human. It can dance, squat, point and “feel” the ground with sensors embedded in its feet, and it will not fall over when shoved.

Designed by Gordon Cheng and colleagues at the ATR Computational Neuroscience Laboratories in Kyoto, the robot was chosen for the experiment because of its extraordinary ability to mimic human locomotion.

As Idoya’s brain signals streamed into CB’s actuators, her job was to make the robot walk steadily via her own brain activity. She could see the back of CB’s legs on an enormous movie screen in front of her treadmill and received treats if she could make the robot’s joints move in synchrony with her own leg movements.

As Idoya walked, CB walked at exactly the same pace. Recordings from Idoya’s brain revealed that her neurons fired each time she took a step and each time the robot took a step.

“It’s walking!” Dr. Nicolelis said. “That’s one small step for a robot and one giant leap for a primate.”

The signals from Idoya’s brain sent to the robot, and the video of the robot sent back to Idoya, were relayed in less than a quarter of a second, he said. That was so fast that the robot’s movements meshed with the monkey’s experience.

An hour into the experiment, the researchers pulled a trick on Idoya. They stopped her treadmill. Everyone held their breath. What would Idoya do?

“Her eyes remained focused like crazy on CB’s legs,” Dr. Nicolelis said.

She got treats galore. The robot kept walking. And the researchers were jubilant.

When Idoya’s brain signals made the robot walk, some neurons in her brain controlled her own legs, whereas others controlled the robot’s legs. The latter set of neurons had basically become attuned to the robot’s legs after about an hour of practice and visual feedback.

Idoya cannot talk but her brain signals revealed that after the treadmill stopped, she was able to make CB walk for three full minutes by attending to its legs and not her own.

Vision is a powerful, dominant signal in the brain, Dr. Nicolelis said. Idoya’s motor cortex, where the electrodes were implanted, had started to absorb the representation of the robot’s legs — as if they belonged to Idoya herself.

In earlier experiments, Dr. Nicolelis found that 20 percent of cells in a monkey’s motor cortex were active only when a robotic arm moved. He said it meant that tools like robotic arms and legs could be assimilated via learning into an animal’s body representation.

In the near future, Idoya and other bipedal monkeys will be getting more feedback from CB in the form of microstimulation to neurons that specialize in the sense of touch related to the legs and feet. When CB’s feet touch the ground, sensors will detect pressure and calculate balance. When that information goes directly into the monkeys’ brains, Dr. Nicolelis said, they will have the strong impression that they can feel CB’s feet hitting the ground.

At that point, the monkeys will be asked to make CB walk across a room by using just their thoughts.

“We have shown that you can take signals across the planet in the same time scale that a biological system works,” Dr. Nicolelis said. “Here the target happens to be a robot. It could be a crane. Or any tool of any size or magnitude. The body does not have a monopoly for enacting the desires of the brain.”

To prove this point, Dr. Nicolelis and his colleague, Dr. Manoel Jacobsen Teixeira, a neurosurgeon at the Sirio-Lebanese Hospital in São Paulo, Brazil, plan to demonstrate by the end of the year that humans can operate an exoskeleton with their thoughts.

It is not uncommon for people to have their arms ripped from their shoulder sockets during a motorcycle or automobile accident, Dr. Nicolelis said. All the nerves are torn, leaving the arm paralyzed but in chronic pain.

Dr. Teixeira is implanting electrodes on the surface of these patients’ brains and stimulating the underlying region where the arm is represented. The pain goes away.

By pushing the same electrodes slightly deeper in the brain, Dr. Nicolelis said, it should be possible to record brain activity involved in moving the arm and intending to move the arm. The patients’ paralyzed arms will then be placed into an exoskeleton or shell equipped with motors and sensors.

“They should be able to move the arm with their thoughts,” he said. “This is science fiction coming to life.”

Wild Green Yonder

Wild Green Yonder: Flying the Environmentally Friendly Skies on Alternative Fuels

From liquid coal to biofuels, military and commercial aviators are searching for domestically sourced, cost-effective and clean alternatives to petroleum-derived jet fuel

 
FOSSIL FUEL–FREE FLYING: The C-17 transport plane pictured here over Manhattan flew from McChord Air Force Base in Washington state to McGuire Air Force Base in New Jersey on a blend of synthetic fuel derived from natural gas and regular jet fuel, the first transcontinental synthetically fueled flight.

In December the U.S. Air Force flew a C-17 transport plane across the country powered in part by a new propellant: natural gas transmuted into a synthetic liquid fuel. Heat and catalysts converted methane into syngas (carbon monoxide and hydrogen) which were then transformed into liquid hydrocarbons (otherwise known as oil and its derivatives): petroleum, gasoline and, in the case of aviation, kerosene.

"Hitler flew Messerschmitts on it," says William Anderson, assistant secretary of the U.S. Air Force for installations, environment and logistics, about such Fischer-Tropsch synthetic fuel, which can be made from methane, coal, plant oils—even wood waste. "We believe that having a secure domestic source of fuel makes it easier for us to do that mission [to fly and fight]. It is less likely that there would be some disruption to the fuel source that we need to fly airplanes."

Whether for supersonic fighter jets or commercial airliners, the aviation world has begun a quest for the fuel of the future, transitioning away from petroleum-derived JP-8 and Jet A varieties to Fischer-Tropsch synthetics or biofuels. Driven by security and environmental concerns as well as skyrocketing oil prices—United Airlines more than doubled its fuel surcharge per ticket to $50 on January 12—the aviation industry continues to cut back on fuel burn as it searches for cleaner, cheaper alternatives.

"We are definitely interested in having an alternative source of energy available to us for both economic and environmental reasons, not to mention pure supply," says John Heimlich, chief economist at the Air Transport Association of America (ATA) in Washington, D.C., which represents airlines responsible for more than 90 percent of U.S. passenger and freight air traffic. "There are a host of fuels out there; some could be better, some could be worse. We need to find something at least as good, if not better."

Rock to Liquid
Jet aircraft today typically burn kerosene, an energy-dense hydrocarbon fuel that delivers as much as 48 megajoules per kilogram (20,700 British thermal units per pound), allowing for long-distance travel. Americans have taken advantage of this capacity, according to the U.S. Bureau of Transportation Statistics: Airlines reported ferrying more than 72 million passengers last July, a record high for a single month.

At the same time, the aviation industry has become far more fuel efficient in the face of soaring prices. (Airlines spent $37 billion for fuel alone in 2007 through November and may follow United in imposing steeper fuel surcharges on customers in 2008.) According to the ATA, the industry has reduced the amount of fuel burned by 23 percent since 2000 by taking such steps as making aircraft lighter and introducing more efficient engines. "Today, Northwest Airlines is averaging roughly 50 passenger miles per gallon [21 kilometers per liter] of fuel," says Tim McGraw, Northwest's director of safety, health and environment, largely by replacing its aging fleet of airplanes with newer, more efficient jets.

The primary reason for such improvements has been the steady rise in fuel costs. For example, the Air Force has watched its energy spending double since 2003 even though it cut fuel consumption by more than 10,000 barrels a day during the same period. "Over 80 percent of the entire Air Force energy buy is in liquid aviation fuel," Anderson says. "That represents a little less than $6 billion a year of taxpayer money that goes into feeding our fleet with fuel."

As a result, the Air Force—and other military branches as well as the Defense Advanced Research Project Agency (DARPA)—have begun to experiment with alternatives. "Alternative fuels offer the potential, if not to lower the price [of petroleum-derived fuels], at least to provide a hedge in the future against their future growth or, put differently, their volatility," says technologist Douglas Kirkpatrick, DARPA's program manager for alternative fuels efforts. "The key here is to go from one source to many."

He adds: "Anyone who runs a business knows that you don't want to have one supplier. Essentially, that's the position we're in."

In the short term, the Air Force hopes to make use of the Fischer-Tropsch chemistry that kept Nazi-era Germany and the apartheid-era Union of South Africa's airplanes flying in the absence of oil (and still supplies 40 percent of South Africa's transportation fuel needs) to ensure diversity of supply. In addition to flying the C-17 across the country—a plane powered by the same Pratt and Whitney F117-100 engine employed on commercial Boeing 757s—the Air Force in August certified its still flying 1950s-era B-52 bombers to burn synfuel.

"Why start with an old weapons system?" Anderson says. "It's a very simple engine compared to newer ones, less things can go wrong."

The natural gas-derived synfuel performed perfectly in both planes during ground tests, flights and even during cold starts in the dead of winter in Minot, N. Dak. The 50–50 blend of synfuel and JP-8 fulfilled all 40 of the Air Force's fuel performance criteria, including coming through in extremely high and low temperatures. "Pilots are telling us that they're feeling no difference at the controls between the fuels," Anderson notes.

Fischer-Tropsch synfuels promise to provide a potentially cleaner fuel supply as well. Burning the purer fuel—clearer than petroleum-derived kerosene—eliminates sulfur emissions that lead to acid rain and reduces (by 50 to 90 percent) the amount of tiny particles that usually remain after combustion, according to Richard Altman, executive director of the Commercial Aviation Alternative Fuels Initiative (CAAFI), an industry effort to develop new energy options.

But synfuel will not lead to fewer emissions of carbon dioxide, the greenhouse gas primarily responsible for global climate change. Environmental group the Natural Resources Defense Council estimates that turning coal to liquid fuel emits twice as much carbon dioxide as producing petroleum fuels. "We will only buy fuel that is greener than our current alternatives," Anderson says. "Our current alternative is petroleum-based jet fuel."

The European Union plans to restrict carbon emissions from airplanes beginning in 2012; in the U.S., legislation is pending that would impose similar limits, and five states (California, Connecticut, Pennsylvania, New Jersey, New Mexico and New York) have petitioned the Environmental Protection Agency (EPA) to regulate such emissions in the interim. "We now know that the solution that will be most environmentally acceptable," CAAFI's Altman says, "will have significant biofuels."

Beyond Kerosene
The amount of emissions from aircraft compared with other vehicles is relatively small—roughly 3 percent of total worldwide greenhouse gas emissions from fossil fuel burning, according to the U.N. Intergovernmental Panel on Climate Change (IPCC)—nonetheless it has a major impact on the climate. By releasing carbon dioxide higher in the atmosphere, airplanes allow the molecule more time to trap heat, also contributing via contrails and other chemically active gases, the IPCC notes.

Some airlines have been effective in reducing greenhouse gas emissions. "At Northwest, our greenhouse gas emissions have gone down 25 percent since 2000 and about 5 percent less than 1990," says Ken Hylander, Northwest's senior vice president of safety and engineering. "If Northwest was a country, we would be Kyoto [Protocol on reducing greenhouse gas emissions] compliant."

But emissions from the aviation industry as a whole continue to climb. According to the EPA, from 1990 to 2005 greenhouse emissions from military aircraft slid by 50 percent but those from commercial carriers rose by 16 percent, largely due to growth in the number of carriers.

Efficiency alone—even in the form of aircraft with improved engines and designs such as the Boeing 787, expected to deliver a 20 percent improvement in fuel efficiency over existing big airplanes—is not the answer. "A low-CO₂ fuel will help us to address that remaining portion of the pie," says David Daggett, technology leader for energy and emissions at Boeing. "That's why we're interested in biofuels specifically."

One such biofuel—ethanol—is already being used to power a heavily employed commercial fleet: piston-engine propeller crop dusters. Max Shauck, chair of the Baylor Institute for Air Science (who flew an ethanol-powered prop plane at air shows in the 1980s), has converted at least 1,000 such aircraft in Brazil, a country that has weaned itself from foreign oil by embracing ethanol domestically produced from sugarcane.

In addition to being easier on the engine, ethanol costs one quarter to one half as much as the aviation gas typically used in such propeller planes. Ethanol decreases the number of hours or distance such an aircraft can fly, however, due to its lower energy density, but "it develops more power and it's a greenhouse gas–neutral fuel," Shauck says. "There's plenty of ethanol produced in the world to power all the piston-engine aircraft."

The Federal Aviation Administration (FAA) is conducting tests but has yet to certify ethanol as a fuel for piston-engine planes in the U.S., says Lourdes Maurice, chief scientist and technical advisor to the FAA's Office of Environment and Energy. Regardless, ethanol's low energy density makes it unsuitable for jet-turbine engines. "Clearly we can't use ethanol," CAAFI's Altman says. "That's a blessing. We don't want to compete with food crops."

Diesellike fuel derived from plant oils might avoid that problem as well as supply similar greenhouse gas reduction (depending on how the plants are cultivated). Already, a Czechoslovakian L-29 jet—specially built in the 1960s by the Czech military to run on alternative fuels—flew for 37 minutes and reached an altitude of 17,000 feet (5,180 meters) powered entirely by reformulated canola oil. "Would you rather buy your oil from the Middle East," asks BioJet 1 copilot Doug Rodante, president of Green Fuels International (a company that promotes alternative fuels), "or the Midwest?"

But biodiesel solidifies into a gel at the cold temperatures found at high altitude, a fatal flaw for any aircraft fuel. The Czech jet has fuel heaters to get around this problem, and similar solutions could be engineered into other jet engines, argues physicist Rudi Wiedemann, president and CEO of Biodiesel Solutions, Inc., in Sparks, Nev., the flight's fuel provider.

Or the biodiesel itself can be further refined to ensure that it doesn't solidify until at least –40 degrees Celsius (–40 degrees Fahrenheit), the current standard for petroleum-derived jet fuel. UOP, a Honeywell Company, has developed such a "green diesel" by heating vegetable and animal oils to add hydrogen atoms to the long hydrocarbon chains, under the aegis of DARPA. In addition, its "ecofining" process adds kinks in the chains to prevent them from easily stacking—or gelling—at cold temperatures, producing a diesellike fuel with as much as twice the combustion quality of the petroleum-derived variety.

Boeing has tested two such "vegetable-based biofuels" with this antifreezing property in the General Electric jet engines used on many of its 747 aircraft, Daggett says. Virgin Atlantic airline announced that early this year it will conduct the first flight test of a biodiesel–petroleum diesel blend in one of the four engines of a 747 aircraft; Air New Zealand is planning a similar test flight on a Rolls Royce engine in one of its 747s later in the year.

The first UOP-derived ecofining facility, capable of producing 100 million gallons of diesel fuel for ground vehicles, is now being built in Livorno, Italy; a second facility is set to be constructed in Sines, Portugal. "Going to biofuels doesn't mean we have to make compromises. We are already making fuels that look exactly like the real thing, or better," says Jennifer Holmgren, UOP's director of renewable energy chemicals. "The real limitation is going to be feedstock."

There is not enough oil from plants such as soy and canola to supply even a fraction of the 60 million–plus gallons of jet fuel burned every day by U.S. aircraft, nearly one quarter of global use, even if all such sources were converted to fuel (which would significantly impact food supplies.) And Boeing has had a hard time finding biofuel suppliers who can produce testable quantities of their product. "Immediately that weeds out a lot of companies when you ask for 1,000 gallons," Daggett says.

As a result, both private companies like UOP, government agencies like DARPA and commercial organizations such as CAAFI have begun to consider a broader array of sources, including the oil from the seeds of Brazil's babassu palm tree or the conversion of the woody or cellulosic parts of plants. Chemical engineer Charles Wyman of the University of California, Riverside, argues for biorefineries turning seed oil, the stalks and other detritus of crop plants, and even wood pulp waste into an assortment of alternative fuels.

"You are growing wood or grasses in a renewable way in some sort of energy plantation to produce biomass," he says. "Convert some of that to ethanol, and the fraction you can't convert, use Fischer-Tropsch to make diesel fuel that could be tailored towards jet fuel."

Or algae could be grown. The tiny plant can produce "60 percent of its weight as oil under stress," according to Wyman. Closed vats might produce pure strains of such high-oil species for feeding into large ponds to grow sufficient supplies, says systems engineer Ron Pate at Sandia National Laboratories in New Mexico, who has been analyzing the fuel potential of microscopic plants.

Such vast algae farms might also subsist on so-called "impaired" water, either salty ocean or polluted waters, Pate says. "Water coming out of sewage treatment plants has nutrients—nitrates, which encourage algae to grow," Boeing's Daggett notes. "You can harvest the algae and extract the oil, then release the water in a cleaner state than what it would have been leaving the sewage plant."

But biorefineries would cost hundreds of millions of dollars and require significant upgrades in existing processes, whereas such algae schemes have yet to be tried. The U.S. Department of Energy (DOE) has provided the money for a few pilot biorefineries and DARPA has provided funding for initial efforts to begin exploring algae's feasibility, but it will be years before any such fuel is widely available. "Ten to 20 years is a reasonable time frame," Daggett says.

Fossil Blends
The Air Force, meanwhile, plans to certify its entire fleet of aircraft on Fischer-Tropsch process synthetic fuels derived from methane or coal by 2011 and plans to purchase enough such fuel to power at least 50 percent of the fleet in the continental U.S. by 2016. Tests began in November on the performance of the purer synfuel in the jet afterburner engines that are used for supersonic flight.

"That's about 400 million gallons [1.5 billion liters] of fuel," Anderson says, compared to 281,000 gallons [1.06 million liters] purchased this year and an estimated 500,000 gallons [1.9 million liters] next year. "It may only be marginally [environmentally] better in 2016. Carbon neutral? Probably not."

Although such synfuels may actually increase greenhouse gas emissions, depending on how they are produced, they will deliver some independence from the tyranny of petroleum. "The coal in the ground in the U.S. at current use will last 400 to 500 years. If you double, triple or quadruple the use of coal, it won't be 400, of course, it'll be 100 or 50 years," Anderson notes. "But it's 50 more years to get to the carbon-free economy."

Before then, the impact on Earth's climate can be limited by blending relatively small amounts of biofuels into such synfuels—an option DARPA, for one, rejects for logistical reasons—or capturing the carbon dioxide from synfuel production and using it to enhance the growth of the plants to be turned into fuel. "Put as little as 20 percent biofuel into nonrenewable fuels—coal-to-liquid and gas-to-liquid—you can be carbon neutral in a mix," CAAFI's Altman says.

Such a 20 percent mix would not require any modifications to existing aircraft engines or infrastructure, Green Flight International's Rodante says. "Jet fuel and biofuel mix is something that is easily done," he says "I don't believe 100 percent biofuel is the answer."

Oil prices at $100 per barrel are already well above the $40 per barrel level at which synfuel producing facilities break even, and even the $70 per barrel level that might make carbon capture economically feasible. "The biggest challenge is production capacity—and staying the course," FAA's Maurice says. "If the price of crude were to drop, can we sustain the interest?"

Still, the combination of factors involved: energy security, diversity of supply and the environment may sustain commercial aviation's interest, though its overall goals are smaller—certifying synfuel blends next year, full synfuels by 2010 and biofuels in 2013. "There is an underlying demand for something better than $90 per barrel oil, that has better domestic supply and can help cope with increasing environmental pressure," ATA's Heimlich says. "I have yet to see that silver bullet magic fuel."

In the interim, many airlines are offering ways to offset the greenhouse gas emissions associated with air travel, such as U.S.-based Delta airline's program with The Conservation Fund to plant trees in return for $5.50 that passengers are given the option of adding to the price of a domestic round-trip ticket or $11 for international round-trip flights. Britain-based Virgin Atlantic has a similar agreement with myclimate (a Swiss offset provider), who uses added flyer fees, which vary depending on ticket price, to fund renewable energy projects in developing countries such as India. It remains unclear, however, how much such passenger-funded partnerships do to alleviate climate change and they are a poor substitute for a carbon-neutral alternative jet fuel.

"We should have stayed the course in the 1970s and then we wouldn't be having this discussion," the Air Force's Anderson says. "Whether it takes 30 or 50 years [to develop such a fuel], it's going to take longer if we start tomorrow than if we start today."