Grow Algae

[bucks native]

from here: http://www.usatoday.com/tech/science...e-energy_N.htm


Aquarium scum: fuel of the future

By Arthur Max, Associated Press Writer

BORCULO, Netherlands — Set amid cornfields and cow pastures in eastern Holland is a shallow pool that is rapidly turning green with algae, harvested for animal feed, skin treatments, biodegradable plastics — and with increasing interest, biofuel.

In a warehouse 200 kilometers southwest, a bioreactor of clear plastic tubes is producing algae in pressure-cooker fashion that its manufacturer hopes will one day power jet aircraft.

Experts say it will be years, maybe a decade, before this simplest of all plants can be efficiently processed for fuel. But when that day comes, it could go a long way toward easing the world's energy needs and responding to global warming.

Algae is the slimy stuff that clouds your home aquarium and gets tangled in your feet in a lake or ocean. It can grow almost everywhere there is water and sunlight, and under the right conditions it can double its volume within hours. Scientists and industrialists agree that the potential is huge.

"This is the ultimate fast-growing organism," says Peter van den Dorpel, chief operating officer of AlgaeLink, which makes bioreactors for speeding reproduction. "Algae is lazy. It eats carbon dioxide and produces oxygen." It has no roots, no leaves, no shoots. "It grows so fast because it has nothing else to do. It just swims in the water."

Farming algae doesn't require much space or good cropland, so it avoids the fuel-for-food dilemma that has plagued first and second generation biofuels like corn, rapeseed and palm oil.

It can grow in fresh water, polluted water, sea water or farm runoff. It can purify a city's sewage while feeding on the nitrogen and phosphates in human waste.

And it is rich in oil. The most common types farmed today have an oil content of 30%, and it can go up to 70% or more.

It also consumes nearly twice its weight in carbon dioxide, the most common greenhouse gas that is discharged by vehicles, power plants and many heavy industries and which scientists say is causing climate change.

Seeking to cut its carbon emissions, the European Union last year mandated that 20% of Europe's energy must come from renewable sources by 2020, up from 8.5% now. Originally, that plan called for a 10% biofuel component for road transportation, but pressure on food supplies prompted a key EU parliamentary committee to vote to scale back that target by as much as half.

Scientists estimate that airlines are to blame for at least 2% of man-made carbon emissions, which could be sharply reduced by algae-based aviation fuel.

One promising idea in climate change technology focuses on capturing carbon from industry and storing it harmlessly in the ground. But algae farms can put that carbon to good use.

"Capturing CO2 is the easiest element" in algae production, says Carel Callenbach, the director of Ingrepro Micro Ingredients, which operates the largest algae farms in Europe, producing 80 tons a year.

Companies have been making biodiesel from algae for years, Callenbach said, but there's no money in fuel. It is expensive to make, and so far it cannot be produced in commercial quantities like ethanol or some other biofuels.

But now, spurred by profit-busting increases in petroleum prices, Boeing and some airlines are exploring whether algae can be refined economically to a kerosene-grade fuel to run their fleets. KLM Royal Dutch Airlines has contracted with AlgaeLink and other companies to scout out prospects.

"The advantage is that it can be used in the present structure. You don't have to totally rebuild airplanes," said Nanke Kramer, a KLM spokeswoman. She said KLM has no results yet from its initial experiments, and it is too early to say whether aviation fuel will be feasible or when the first flight tests would take place.

Rene Wijffels, a professor of bioprocess engineering at Wageningen University and Research Center in the Dutch town of Wageningen, said he did a feasibility study last year for an energy company on algae for fuel, and was surprised by the results.

"We did not believe it would ever be possible for energy production," he told The Associated Press. "We found the costs were high but not as high as we thought." At $3.20 per pound," he said, "it was too expensive for a biofuel — but not that far away."

Biofuel production is shackled by two factors: the limited availability of nutrients, and an unfavorable energy balance. "If you use the present technology, you will put in more energy than you get out," Wijffels said.

Those problems can be solved, but it will take time and investment, he said.

The race to make gas from goo is on around the world. Industries, institutes and universities from Argentina and Brazil to New Zealand are pouring millions of dollars into new technologies. In the United States, Arizona State University is trying to develop an aviation fuel, Brunswick Community College in North Carolina is exploring ways to extract oil from algae with ultrasonic waves, and dozens more facilities are sorting out which of the hundreds of thousands of algae types bloom fastest with the richest attainable oil.

The Netherlands has long been ahead in farming technology and has one of the world's highest crop yields. With as many barnyard animals as its 16 million people, it is the world's second largest exporter of agricultural products after the United States.

At Ingrepro's algae farm in Borculo near the border with Germany, the scum from the 21,500-square-foot pool is filtered and processed into flaky green strips that crumble to the touch. The carbon exhaust from the steam engine used to dry the algae is pumped back into the pool.

Algae oil goes into paints, resins and bioplastics. Fuel has the lowest value of any product, said Callenbach. The key to profiting from algae farming is in the cake left over after extracting the oil. Ingrepro turns it into dozens of products, from horse feed to weed killer for golf courses. As a food additive for humans, it is a source of healthy omega-3 fatty acids.

AlgaeLink, by contrast, sells bioreactors rather than algae products. It nurtures the algae in a closed and controlled environment of clear tubes, speeding the reproductive process by two to four times as the water turns darker almost before your eyes.

But the process requires much more energy than open pools.

Van den Dorpel says making jet fuel will be viable within a few years if petroleum prices stay above $100 a barrel. Callenbach says algae fuel may be profitable in about five years.

Wijffels is skeptical. "Five years? I'm a little more pessimistic than that. But maybe that's the role of a scientist."

Copyright 2008 The Associated Press. All rights reserved. This material may not be published, broadcast, rewritten or redistributed.

[aaron38]

This really is going to be a very important technology for the future. We may with electric vehicles be able to shift our transportation energy off oil, but we use oil for a lot more than gasoline. One of the most important uses of oil is manufacturing fertilizer. Oil from algae will be needed someday just to keep farming going to feed 7-8 billion people.

[nomarandlee]

Quote:

http://news.bbc.co.uk/2/hi/science/nature/7661975.stm

Page last updated at 16:56 GMT, Thursday, 9 October 2008 17:56 UK


In bloom: growing algae for biofuel

By Paul Henley
BBC News, Roosendaal

"It's exciting because it's achievable," says Peter van den Dorpel, as he looks over the big plastic tubes full of various shades of green algae.

His company has designed, produced and marketed the crop in its bid to be the first to provide the aviation industry with a feasible alternative to fossil fuel.

We are standing in an enormous greenhouse near Roosendaal in the south of The Netherlands.

Most of the greenhouse is growing tomatoes with impressive efficiency. One corner is dedicated to the cultivation of algae - in a similarly efficient way, according to Mr van den Dorpel.

"It's actually like growing tomatoes; the algae need similar things," he says.

This crop uses the warmth, light and a steady feed of carbon dioxide and nutrients to reproduce faster than any other plant on earth.

The amount of algae in these tubes can double daily. And that is both the attraction and the problem with algae as a commercial crop.

What Algae-Link's system claims to crack, possibly for the first time, is the problem of clogging. A patented internal cleaning system keeps the set-up harvesting twenty-four hours a day.

Once the cells of the algae are split into their constituent parts (an established science with all biofuel crops but a more secretive part of the process in this case), the green mass can be sold as feed for fish and oyster farms and the vegetable oil can be processed into engine fuel.

What will be crucial is to produce the raw material in sufficient quantities. Cynics are saying a land mass anything up to the size of Ireland would have to be devoted to algae production to fuel the world's civil aviation industry.

But that may not be out of the question. With algae cultivation in tubes, farming is feasible on otherwise unusable land; there are already projects up and running in the Gobi desert of northern China.

CO2 eater

But the big "green factor" associated with algae is that it needs CO2 to grow.

About 1kg of algae is reported to "eat" 3kg of CO2, which means tubes of algae could be laid out on brownfield sites next to a power station or a food processing plant to soak up emissions.

Algae-Link in the Netherlands already has a tie-in deal with KLM/Air France.

In fact, almost all the major airlines are keen to be the first to get a passenger plane in the air powered entirely by green energy alternatives and, as things stand, algae is looking the best bet.

The fact that not a single jet plane has yet flown on algae-based fuel is not stopping some in the industry confidently predicting it happening as soon as 2010.

Certainly, Europe's biggest aircraft maker, Airbus, based in Toulouse in the south of France, welcomes the idea.

Russ Walker, their chief scientist in charge of researching greener fuels, tells me algae biofuel will be "very good for our customers (the airlines) because they are potentially going to be charged, through EU legislation, for their CO2 emissions.

He adds: "Therefore, if they can have a product which is more environmentally friendly, it is a big advantage for them. And what's good for our customers is good for us."

Economics, then, may prove to be the driving force.

Some environmentalists are sceptical. Greenpeace think the speculation about algae provides a handy green disguise for the aviation industry which is actually anything but green.

"There are many questions about it", says Douglas Parr, chief scientific advisor for Greenpeace UK.

"How much land will it use? How efficient will it be? Will it ever be commercially demonstrated? But our main worry is that it comes as a distraction from the fact that aviation has got to do plenty of things aside from algae research in order to become truly sustainable."

Back in the greenhouse in Holland, algae pioneer Peter van den Dorpel is sticking to his guns. Economies of scale, he insists, will not defeat him.

"While we speak, we are expanding thousands and thousands of square metres of sites in greenhouses here in Holland and in the open air in the south of Spain and in China. So we are ramping up these locations to very significant areas of land."

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Researchers turn algae into high-temperature hydrogen source


November 12, 2009

http://www.physorg.com/news177242747.html

Quote:

In the quest to make hydrogen as a clean alternative fuel source, researchers have been stymied about how to create usable hydrogen that is clean and sustainable without relying on an intensive, high-energy process that outweighs the benefits of not using petroleum to power vehicles.

- This image shows the process by which Photosystem I in thermophilic blue-green algae can be catalyzed by platinum to produce a sustainable source of hydrogen. The system was highlighted in a paper by University of Tennessee, Knoxville research Barry Bruce, et al. in Nature Nanotechnology. Credit: Barry D. Bruce/University of Tennessee, Knoxville