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The Quest for Alternative Fuel in the Aviation Industry Takes Off

By James DiGeorgia, The Gold and Energy Advisor
November 24, 2008 | 14 Comments

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It's one of the busiest travel seasons of the year and it's almost here. The Thanksgiving holiday is notorious for crowded airports, long lines and flight delays. And while you may not be flying on an airplane powered by alternative fuel to get to Thanksgiving dinner this year, scientists are studying the possibilities now more than ever.

With more than 75,000 scheduled commercial flights per day in the world, finding an alternative fuel source is crucial. The aviation industry produces only about one-ninth as much carbon dioxide as motor vehicles do. But, because these gases have a much greater impact on the upper layers of the atmosphere, scientists say the potential for danger is that much greater. As the aviation industry grows and newer aircraft are produced that can fly quieter and farther, alternative fuels that can power these flying machines would likely be the next logical, eco-friendly step in their development.

The airlines are actively working to reduce their emissions. Over the last 30 years, U.S. car manufacturers haven't cut motor vehicle emissions at all — while civil aviation has cut its environmental impact by 70 percent (as measured per passenger mile).

In addition, the industry is eager to continue its aggressive carbon-cutting measures. The Air Transport Association wants to cut emissions by 30 percent per passenger by 2025. Meanwhile, the Commercial Aviation Fuels Initiative (an alliance of industrial companies, university researchers and various government agencies), is working to establish a purely biological jet fuel by 2013.

Jet fuel has to be very energy-dense since a plane has limited volume and weight capacities in its fuel tanks, and a fuel containing less energy will reduce the aircraft's range. This is a huge technical challenge facing engineers and designers because this means ethanol and other currently available biofuels won't work as jet fuels.

Another dilemma is the impact this would have on the farming industry. Ethanol and other biofuel crops can't be cultivated in large enough quantities for the volume of fuel required. According to some estimates, we would need to convert the entire continental United States over to corn production if we wanted to fly airplanes with corn ethanol.

The aviation industry is intensely studying "second generation" biofuels, such as nut oils from jatropha curcas (Barbados nut) and babassu. These oils are more energy-dense than ethanol. As a bonus, many of these oils cannot be consumed by humans, so we wouldn't be making fuel from food.

Even these oils can't supply all of aviation's needs, though. Most industry experts agree that the best long-term solution is likely to come from algae. The benefit to algae is it can produce an oil yield up to 15 times that of other biofuel plants. In theory, every airplane in the world could be supplied by a total cultivated area the size of West Virginia. The other advantage is that some algae actually consume greenhouse gases during their cultivation, rather than producing it (as corn ethanol production does).

Industry experts say the upside is tremendous.

"Airlines, along with airframe and engine manufacturers, have made enormous strides regarding efficiency, but the industry still runs on oil," said Seth Kaplan, managing partner of Airline Weekly, an industry publication. "It makes environmental and economic sense to reduce dependency on this one commodity, and whoever can develop a viable alternative will have a lot of eager customers."

A huge amount of money is about to be spent on incorporating biofuels into aviation. The solution that emerges will be deployed on a worldwide scale and the company that creates that solution will be the next big name like Microsoft or Google.

James DiGeorgia is editor and publisher of the Gold and Energy Advisor Newsletter and the author of the book, The Global War for Oil.

Bioenergy

The information and views expressed in this article are those of the author and not necessarily those of RenewableEnergyWorld.com or the companies that advertise on its Web site and other publications.

14 Reader Comments

Comment
1 of 14

mike-zagorsky-136998

November 24, 2008

At the price of being cynical, in this instance I have no issue with aviation continuing to rely on petroleum fuels for the foreseeable future. It represents a small percentage of total petroleum consumption and by far the benefits it brings the world outweigh it's environmental costs.

After all, Diesel and jet fuel are basically refined from the same hydrocarbon range. Therefore, alternatives to ground based diesel fuel would have an equal impact on net petroleum consumption while at the same time not have to meet the same technical standards are a JET-A equivalent.

So using electrified rail, biomethane for trucks, PHEVs, biodiesel, et al would have the same net impact on petroleum consumption vs. developing JET-A biofuels. The former sounds easier to me.

Comment
2 of 14

dominic-jermano-62365

November 26, 2008

I think new airline fuel will encompass a new type of airliner. One of the most powerful pressures is using steam, that can be produced via microwave electric pulse into thermos tanks that already have a hot temp. thereby using small amounts of electricity to reach the steam levels...which would circulate.

Another great option is using the pollution in the atmosphere as a fuel resource. Tapping that resource is a very real component to gases being used that are refined while in the atmosphere.

Comment
3 of 14

robert-whitson-69681

November 26, 2008

I was disappointed to see that this article only focused on hydrocarbon-based fuels with no mention of developing hydrogen-powered aircraft - water vapor is, of course, already present in the atmosphere.

Earlier this year Boeing conducted a test flight of a hydrogen-powered plane (http://news.bbc.co.uk/2/hi/technology/7330311.stm). However, even though the tests were successful, Boeing claimed that they didn't think "fuel cells could be the primary power source for large passenger aircraft." I'm sure Boeing's R&D budget has experienced drastic cuts over the last couple years, which might explain their lack of will in taking the risk to develop this technology, but fuel cells represent a genuinely clean alternative that is capable of meeting the power demands of large aircraft.

Comment
4 of 14

ian-rowe-141393

November 26, 2008

Air New Zealand biofuel test flight all set. The world's first commercial aviation test flight powered by a sustainable second-generation biofuel is ready to go next Wednesday 3 December 2008

The jatropha fuel has now been blended 50:50 with standard Jet A1 fuel by Air New Zealand at its Auckland Engineering Base. The biofuel blend, named J50, has now been transferred into an RNZAF fuel tanker ready to fuel the Air New Zealand Boeing 747-400 early next week.

The two-hour test flight is scheduled to take off from Auckland airport on Wednesday morning 3 December, with the jatropha biofuel blend powering one of the Air New Zealand Boeing 747-400's Rolls-Royce RB211 engines.

keep New Zealand green

Comment
5 of 14

hitoshi-maruyama-58931

November 26, 2008

According to National Renewable Energy Laboratory, algae produce biodiesel from 5.000 to 20,000 gal/acre. It also reported that algae which contain 50 % of oil can be grown at 50 g/m2/day.
I have no idea how much jet-fuel is needed to satisfy world-wide demand, the cultivation of algae for the demand would require a huge cultivation farms.
I believe that we have to concentrate extensively to develop technology to produce them in a large amount in a short life cycle.
what i think is that we should divide transportation in two, one is high speed trains for less than 1,000 miles at 200 mph or faster and two is airplanes for beyond the distance.
High speed trains can be run renewable energy. Other ground transportation systems including trains slower than 100 mph and buses should fill outside space of high speed trains and airplanes service areas. All ground systems can run on renewable energy.
The fuel for airplanes is pet-oil until bio-jet fuel technology becomes mature and supply all jet fuel.
Trains can be environmentally clean using renewables. They are very energy efficient, They need only from 1/5 to 1/12 of energy per passenger base of cars and 1/8 of energy of airplanes.

Comment
6 of 14

-warren-reynolds-145720

November 26, 2008

Mr. DiGorgia: I am surprised you did not mention hydrogen as a fuel. In 1957, NASA tested a B-57 bomber using hydrogen in place of the jet fuel. It was successful. With the new light-weight carbon fiber tanks that can hold hydrogen at 10,000 psi, it has the highest energy density of any fuel and is lighter in weight. With Boeing's new carbon fiber lighter weight jet liner, the hydrogen propulsion would be an ideal combination.

Comment
7 of 14

-warren-reynolds-145720

November 26, 2008

Sir: Correction, DiGeorgia. sorry about the mis-spelled name.

Comment
8 of 14

jeff-wishart-163599

November 26, 2008

I am no Big Three sycophant, but it is patently false to claim that "Over the last 30 years, U.S. car manufacturers haven't cut motor vehicle emissions at all". For example, a 2007 Ford Fiesta MK6 (UK car) produces over 98% less NOx, CO and HC than did a 1976 Ford Fiesta MK1. In the U.S., the fuel consumption of the average car decreased between 1975 and 2008 by some 35% (GHG emissions are directly related to fuel consumption). More cuts to both criteria air contaminants (CACs) and GHGs could certainly have been made, and I hold strong hopes that we will see a real change in powertrain technology; however, it is important that advocates for green energy not overstate their cases and present falsehoods that allow the naysayers an opening to dismiss our arguments.

Comment
9 of 14

jeff-wishart-163599

November 26, 2008

Warren Reynolds: there is a difference between "energy density" and "specific energy" that I think you have missed. Energy density has units of Wh/L while specific energy has units of Wh/kg. Therefore, your statement that hydrogen "has the highest energy density of any fuel" is not true--but will be if you change it to specific energy.

Comment
10 of 14

peter-h-c-schroeder-154416

November 28, 2008

Maybe we better focus investment on high capacity communication technologies (wireless or broadband with audio-visual support and enhance teleconferences), strive to reduce frequent and long distance travel and enjoy feeling comfortable not only with gained personal time but also with growing credit points on our saving accounts for avoided GHG emissions. Reducing our ecological footprint and improving resource efficiency balance will be more decisive for our sustainable future than temporary solutions with fuel from algae, jatropha and other fuel commodities which finally all have difficulties to compete with GHG-reduction achieved through a new paradigm focussed on lower transportation needs.

Comment
11 of 14

russ-finley-53703

November 29, 2008

If only it were that simple:

"Making Biofuel out of Small Farmers"

http://gristmill.grist.org/story/2008/11/24/203023/24

"...A final interesting point is that planting a non food crop like castor or Jatropha (both contain toxins and are inedible) benefits the biodiesel refiner as it means that there is no market competition for the farmer's production. For the farmer it limits their options, but more importantly, the crops can't be eaten if the refiner doesn't deliver as is the case in the above story..."

Comment
12 of 14

tim-acland-126986

November 30, 2008

I feel bad for criticising someone who is contibuting to what I see as a worthy cause, but I think the standard of this article is low.

For example, seed oil derivatives are not normally considered a second generation biofuel. Second generation biofuels are those which aim to offer a step change in energy harvest density by using the 'whole plant' - to harness a larger fraction of the plant's energy reserves than just the seed oil or carbohydrates.

While seed oil derivatives can provide a much higher "well-to-wing" energy yield compared to ethanol, mainly due to the lower energy consumption in it's manufacture, true second generation fuels such as cellulosics or waste derived products need all the publicity they can get - I'm shocked by the lack of attention they get in this article.

Comment
13 of 14

fred-linn-151968

November 30, 2008

--------"Even these oils can't supply all of aviation's needs, though. Most industry experts agree that the best long-term solution is likely to come from algae. The benefit to algae is it can produce an oil yield up to 15 times that of other biofuel plants. In theory, every airplane in the world could be supplied by a total cultivated area the size of West Virginia. The other advantage is that some algae actually consume greenhouse gases during their cultivation, rather than producing it (as corn ethanol production does)."------

This statement from the article is untrue. All biofuels are produced from plant sources that must remove CO2 from the atmosphere. If they do not remove the CO2 from the atmosphere, the plants can not carry out photosynthesis---hence, no crop. No crop, no biofuel.

Also, sorry folks, this is NOT new and untried technology. Germany developed and deployed rockets and jet aircraft powered by synthetic and biofuels including methanol and ethanol in World War 2, including the world's first operational jet aircraft the Me-262 Swallow, the manned rocket aircraft, the Komet, and the unmanned V-1 and V-2 ballistic missles.

These fuels were produced using coal and wood sources using the Fsischer-Tropsch process, which can be adapted to produce alcohols, and also long chain hydrocarbons.

This was all being done almost 70 years ago.

Fischer-Tropsch can produce ethanol and/or longer carbon chain molecule output by adjusting temperature and catalyst parameters, and uses any type of plant cellulose feedstock.

Fischer-Tropsch process is the process that will be used in a plant being constructed right now in Soperton, GA, that will produce 100 million gallons per year of ethanol from logging and millwork waste wood.

Comment
14 of 14

fred-linn-151968

January 4, 2009

----"Air New Zealand has become the first airline to test a 50/50 blend of the green fuel in a Boeing 747-400 passenger jet:"--------
-------"The flight lasted two hours and ran one of the plane's Rolls-Royce engines on the jatropha biodiesel blend. Air New Zealand has previously stated that they want to become the world's most sustainable airline and hopes that by 2013, 10% of its flights will be powered by biofuel blends such as the jatropha biodiesel blend used in this test flight.

Air New Zealand said the the jatropha used to make the fuel came from South Eastern Africa (Malawi, Mozambique and Tanzania) and India. They also claim that the oil was produced from Jatropha seeds grown on "environmentally sustainable farms."

As a second generation biofuel, jatropha is grown on land that doesn't compete with food. Jatropha requires almost no care and very little water. Another major benefit of jatropha is that, due to its ability to take hold in harsh wastelands, it can be used to help stop erosion in these areas and reclaim them for agricultural production."-------

From the article: Kiwis Make First Jatropha Biodiesel Flight

link: http://domesticfuel.com/2008/12/30/kiwis-make-first-jatropha-biodiesel-flight/

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