Biofuels in Europe: Part 1

  • The National Renewable Energy Laboratory's cellulosic ethanol plant. (Photo courtesy of the National Renewable Energy Laboratory)

The US government is spending
millions of dollars to build bio-energy
plants. They’ll turn everything from
wood chips to algae into energy. But
these facilities are years behind what
they are already doing in Europe –
especially in Germany. In the first
part of our three-part series on biofuels
in Europe, Sadie Babits takes us to one
German plant that makes green energy
on a massive scale:

Transcript

The US government is spending
millions of dollars to build bio-energy
plants. They’ll turn everything from
wood chips to algae into energy. But
these facilities are years behind what
they are already doing in Europe –
especially in Germany. In the first
part of our three-part series on biofuels
in Europe, Sadie Babits takes us to one
German plant that makes green energy
on a massive scale:

We’re in Eastern Germany where crews work on what looks like brew vats.

(construction sound)

These monster tanks remind me of vats for brewing beer, except these vats will brew energy from fermenting rye, manure and bacteria.

“Basically, we’re standing here in front of the biogas and bio fertilizer production area. The big fermenter is for the biogas production.”

Oliver Lutke is our tour guide. He’s really a chemical engineer for Verbio. The company is one of Germany’s largest commercial producers of biofuels. Lutke’s been involved in turning this ethanol facility into a plant that makes ethanol and biogas. That’s methane.

“We convert everything into energy by using biological processes. This combination biogas and bioethanol production plant isn’t existing in the world.”

That’s what Verbio claims anyway. The company buys grain from some four-thousand farmers in the region. The grain gets turned into biogas and ethanol. Verbio then turns the minerals from making these biofuels into fertilizer.
That goes back to the farmers for their crops.

“We’re closing the loop to the farmer converting all the carbon to energy and the minerals going back to the farmers as fertilizer which is growing the plants used to extract the energy.”

Lutke says the company has the technology to make this industrial sized plant profitable. That baffles skeptics because it costs a lot to make green energy. You have to buy the grain. And the actual process of turning that grain into fuel can be really inefficient. By the time you’ve made one gallon of biofuel, that gallon of oil is cheaper.

Jan Liebetrau isn’t convinced Verbio has the answer. He researches bioenergy and its potential in Germany.

“If you put lots of energy into the system and you get bioethanol you’re putting more energy in than you get out.”

So making bio ethanol costs energy, which defeats the whole purpose of producing it in the first place. Lutke doesn’t see it that way. He says Verbio has the technology to make biofuels without losing energy. And because the company’s process is more efficient, Lutke says they’ve cut down on greenhouse gas emissions.

“We emit 200,000 tons and the plants we are using will eat off 180,000 tons and that’s a closed cycle.”

It’s not perfect, but there’s less greenhouse gas being released than, say, from an oil refinery. Lutke is convinced bio energy will play a big role in cutting greenhouse gas emissions.

Germany, and Europe for that matter, have become leaders on this. Germany wants to be the first industrialized nation to be powered entirely by renewable energy – a goal Germany could reach by 2050, well ahead of the U.S.

For The Environment Report, I’m Sadie Babits.

Related Links

Energy Bill to Include Boost for Biomass?

  • Biomass is catch-all term for technology that turns things like wood chips into energy or heat. (Photo by Susan Mittleman)

Congress could wrap up a huge energy bill by this fall.
It could include a minimum renewable energy standard for
utilities. That’d mean more wind and solar-generated power.
Shawn Allee reports biomass could get a boost, too:

Transcript

Congress could wrap up a huge energy bill by this fall.
It could include a minimum renewable energy standard for
utilities. That’d mean more wind and solar-generated power.
Shawn Allee reports biomass could get a boost, too:

Biomass is catch-all term for technology that turns grass, wood chips, or even algae into energy or heat.

It’s usually ignored in political discussions, but Vermont Senator Bernie Sanders brought it up in a recent hearing.

He says he was inspired by a power plant he saw at Middlebury College.

“I went to a plant they have on campus which is using wood chips replacing oil they are saving $700,000 a year and creating local jobs and cutting greenhouse gas emissions.”

Congress is considering what kind of plants and agricultural waste might qualify as “renewable biomass energy.”

Some energy analysts say some plants shouldn’t be included, since it could take too much energy collect and transport them.

For The Environment Report, I’m Shawn Allee.

Related Links

Lake Algae and Lou Gehrig’s

  • Example of cyanobacteria blooms on Bow Lake in Bow, New Hampshire (Photo courtesy New Hampshire Department of Environmental Services)

There’s a kind of blue and green scum that can bloom in lakes and ponds across the nation. This scum is called cyanobacteria. For years, scientists have known that this stuff can produce dangerous toxins. Amy Quinton reports now researchers are studying whether there’s a link between cyanobacteria and Lou Gehrig’s disease:

Transcript

There’s a kind of blue and green scum that can bloom in lakes and ponds across the nation. This scum is called cyanobacteria. For years, scientists have known that this stuff can produce dangerous toxins. Amy Quinton reports now researchers are studying whether there’s a link between cyanobacteria and Lou Gehrig’s disease:

Jody Conner reaches into his refrigerator in his lab.

“This is the cyanobacteria that we’ve collected. This one comes from Harvey Lake. See how green that sample is?”

He’s the Director of New Hampshire’s Limnology Center.

Conner has been collecting samples of cyanobacteria from lakes across New Hampshire.

It looks like green scummy algae on the surface of the water that can be several inches thick.

But it’s actually bacteria.

Conner says cyanobacteria feed on nutrients like phosphorus and nitrogen that can come from runoff of lawn fertilizers or sewage.

“They need sunlight, phosphorus, and they seem to like the warmer waters. So, they really grow in mass numbers when they have all three of those.”

Jim Haney is a professor of biological sciences at the University of New Hampshire.

He says, in high enough concentrations, some cyanobacteria blooms can produce more than 70 different kind of liver toxins called microcystins.

“That scum can be toxic enough that it’s been estimated that only about 17 milliliters is enough to kill a small child. 17 milliliters is just a couple of teaspoons.”

Cyanobacteria blooms can also produce neurotoxins.

Haney, and other researchers, have embarked on research to find out if there’s a connection between cyanobacteria and patient’s with Lou Gherig’s disease – also known as ALS.

The research began when Doctor Elijah Stommel began mapping hundreds of ALS patients across New Hampshire.

Stommel is a neurologist at Dartmouth Hitchcock Medical Center.

He noticed the incidence of ALS was 2.5 times greater than the national rate around lakes known to have had significant cyanobacteria blooms.

Stommel says he found a particularly high cluster of patients on one lake in the western part of the state.

“We were able to establish that there appeared to be about a 25 fold increase in what one would expect to see for the ALS incidence.”

But he’s not sure if cyanobacteria are the culprit.

A few scientific studies have shown a particular type of neurotoxin found in cyanobacteria is also found in patients with ALS.

The neurotoxin is known as BMAA.

But it’s not known whether BMAA can trigger ALS.

Jim Haney says more research is needed.

“We know that, in the laboratory, a wide range of different types of cyanobacteria are able to produce BMAA. So, one of our goals this summer is to determine whether there are BMAA molecules in our lakes.”

So far, researchers haven’t found BMAA, and there are still a lot of unknowns about how people could be exposed.

Do you have to drink it or can you breathe it in the air?
How long do you need to be exposed to it before it causes damage?

Again, Doctor Elijah Stommel.

“If there is a link between cyanobacteria blooms and the toxins they make, and a neurodegenerative disease like ALS, then I think we should pursue that with as much vigor as we can. And I think the neurology literature would suggest there is an environmental trigger for ALS.”

But, scientists have not yet found that link.

If they do, Stommel says that link might help find ways to prevent the dangerous toxins, or block their effects.

For The Environment Report, I’m Amy Quinton.

Related Links

Algae Fuel Aspirations

  • A net drags floating algae toward the boat (Photo by Ann Dornfeld)

Algae is attracting a lot of
attention and investment as an alternative
energy source. It grows quickly, contains
a lot of oil, and doesn’t take up valuable
farmland. Ann Dornfeld profiles one company
that’s trying to turn algae into fuel:

Transcript

Algae is attracting a lot of
attention and investment as an alternative
energy source. It grows quickly, contains
a lot of oil, and doesn’t take up valuable
farmland. Ann Dornfeld profiles one company
that’s trying to turn algae into fuel:

I’m standing on a pontoon boat floating just a few feet off the shore of a saltwater bay.
Two men are standing in the waist-deep water around the boat. They’re guiding a layer of
floating algae into a funnel that’s sucking the algae into a burlap bag.

(sucking sound)

It’s an algae harvest – and James Stevens is directing the process. He says they
have to be careful not to suck up young salmon or other animals along with the
algae.

“This junction can be turned on, and it allows me to feed water into a box where
then I can sort and make sure there’s no by-catch actually coming through the
system.”

Stevens is Vice President and Chief Scientist of Blue Marble Energy. It’s
a Seattle start-up trying to turn algae into fuel. Most algae-to-energy researchers
are growing algae in giant tanks. Blue Marble has a different plan: gather algae
that’s already growing in noxious blooms along coastlines.

(sound of waves)

Here in Dumas Bay, not far from Seattle, huge blooms of algae often rot in the
water. That process uses up oxygen and kills marine life. And when the dead algae
washes up on the beach, it creates a smell the neighbors hate.

Blue Marble President Kelly Ogilvie says these algae blooms are common
around Puget Sound – but that’s nothing compared to more polluted waterways
elsewhere in the world.

“And the most recent, I think, salient example was Qingdao, China. And the
bloom that occurred there was, I think, like 800 square miles and they pulled a
million tons out of the water and that is prologue to what is going to be happening
on coastlines across the planet.”

Warmer water can help algae grow, and some scientists think global warming is
contributing to an increase in gigantic blooms. Nutrients from sewage dumping
and fertilizer runoff from farm fields and lawns also help algae flourish.

“If you think about what is actually happening in our oceans, the algae bloom
crisis has just begun. And if we can find a way to turn that new crisis into a
solution to something else, by goodness we’re going to try and make a go at it.”

Most companies doing algae-to-energy research focus on creating biofuels for cars
or jets. Instead of liquid fuel, Blue Marble wants to convert algae into natural gas
and biochemicals.

Along with private investment, Blue Marble has a contract with the Washington
Department of Ecology to collect algae at two bays in Puget Sound.

The department’s Alice Kelly is watching today’s harvest from the beach. She says
her agency hopes this gets rid of the rotten egg smell neighbors have been
complaining about without hurting the ecosystem, the sealife near the shore.

“It’s very important to protect that habitat. So we’re walking a very fine line here
between trying to deal with the excess odor problem and protect the near shore.”

Blue Marble’s approach provides that protection, she says, because its operation is
based just offshore. They aren’t dragging equipment across the beach. And today,
it looks like the only by-catch has been other species of algae.

But some conservationists have big concerns about harvesting wild algae for fuel.

One of them is Kevin Britton-Simmons, a researcher at
the University of Washington. He says a lot of unnatural algae blooms could be
prevented by keeping fertilizer and other pollutants out of the water.

“I feel this is essentially exploiting the problem instead
of fixing it. I’m concerned if we allow a business to develop that’s dependant on
this problem, what’s gonna happen when we fix the problem? Will there then be
pressure for this business to harvest natural populations of algae?”

Natural blooms are a valuable part of the food web, and he says removing them
could rob marine life of a major food source. He says it’s also hard to distinguish
between natural algae blooms and those caused by pollution.

(sound of waves)

Back on Dumas Bay, Kelly Ogilvie says his company has netted nearly 10,000 pounds of algae from the two harvests it’s completed. The next step is to
use bacteria to break down the algae into natural gas and various chemicals.

If all goes as planned, Ogilvie says Blue Marble’s first batch of natural gas will be
ready any day now.

For The Environment Report, I’m Ann Dornfeld.

Related Links

Green Fuel From Green Slime

  • Roger Ruan directs the Center for BioRefining at the University of Minnesota. He's experimenting with algae that grow quickly in the nutrients in wastewater. He says the oil-rich algae are a potential source of biodiesel. (Photo by Stephanie Hemphill)

When people talk about bio-fuels,
they usually mean ethanol from corn or diesel
fuel from soybeans. But there are lots of
possibilities. One of them is algae. Algae
contains a lot of oil. The US Department of
Energy experimented with algae for nearly
twenty years after the oil crisis of the 1970s.
But with fuel prices so high, scientists around
the world are looking at algae again. Stephanie
Hemphill reports one researcher thinks
he’s figured out how to grow lots of algae, fast:

Transcript

When people talk about bio-fuels,
they usually mean ethanol from corn or diesel
fuel from soybeans. But there are lots of
possibilities. One of them is algae. Algae
contains a lot of oil. The US Department of
Energy experimented with algae for nearly
twenty years after the oil crisis of the 1970s.
But with fuel prices so high, scientists around
the world are looking at algae again. Stephanie
Hemphill reports one researcher thinks
he’s figured out how to grow lots of algae, fast:

Roger Ruan has been trying for years to figure out how to turn algae into diesel,
economically. He’s the director of the Center for BioRefining at the University of
Minnesota.

Ruan says there’s no question it can be done; some people are already producing algae
oil. They’re growing it in open ponds. It’s used for pharmaceuticals, food supplements,
and cosmetics.

“Right now, based on an open pond system, per acre per year, you can easily get 5,000
gallons of oil, and soybean would probably give you 50. That’s 100 times difference.”

So algae can be far more efficient at producing diesel fuel than soybeans. But how do
you grow enough algae to make a dent in the nation’s energy demand?

Ruan is turning to an unlikely partner: the local sewage treatment plant.

“Wastewater has lot of nutrients: phosphorus, nitrogen, are all available in wastewater,
and actually you spend lot of money to remove these from wastewater, so if we can kill
two birds with one stone, that would be the best, and that’s what we’re hoping to do.”

(sound of treatment plant)

St. Paul, Minnesota’s sewage treatment plant sits on the bank of the Mississippi River.
The basement of the building where the solids are separated from the liquids is a
brightly lit space. It’s filled with big steel pipes and valves and tanks.

Off to one side, Ruan’s team is setting up a rack of aquariums – the future home of juicy
green algae. When everything is ready, some of the partially-treated waste will be
diverted into the tanks, where it will feed the algae.

The waste is still full of stuff that’s bad for the river, but good for algae.

“It’s got a fair amount of phosphorus, and some ammonia nitrogen that the algae are
going to need.”

Bob Polta is manager of research and development at the treatment plant.

It’s easy to see why he likes this idea: every day the facility has to remove 4 tons of
phosphorus and more than 16 tons of nitrogen from the waste stream.

The algae experiment, if it works, will allow them to do some of that removal in a more
cost-effective way. And this could be the answer to Roger Ruan’s problem of trying to
create enough algae to make enough oil to compete with petroleum diesel.

Polta says there’s a big potential, both for cleaning wastewater and for producing
energy in the same place.

“All the wastewater treatment ponds in the small communities around the state are
essentially using algae to treat wastewater; it’s just that they’re not being harvested. It’s
just that we’re getting two goals together here, and two research groups, one is essentially taking algae and
harvesting the oil and making biodiesel, and the other is using algae as a treatment
scheme, and to see if we can make this thing really fit.”

Polta expects by the end of the year he’ll know more about whether this is a practical
idea.

Roger Ruan says within six-to-ten years someone, somewhere, will be producing diesel
from algae on a commercial scale.

For The Environment Report, I’m Stephanie Hemphill.

Related Links

Green Goo Finds New Home

  • Sandy Binh works for the Waterkeeper Alliance. She's kept a close eye on water quality problems in western Lake Erie. She and her neighbors are worried about the emergence of a new algae in the Lake - Lyngbya wollei. (Photo by Mark Brush)

Life along the water can be pretty nice – sunsets, strolls along the
beach, and boating. It’s no wonder more Americans are moving closer to
big lakes. But it’s not all fun at the beach these days. Mark Brush
brings us the story of one lake shore community that seems to be stuck
with a green gooey invader:

Transcript

Life along the water can be pretty nice – sunsets, strolls along the
beach, and boating. It’s no wonder more Americans are moving closer to
big lakes. But it’s not all fun at the beach these days. Mark Brush
brings us the story of one lake shore community that seems to be stuck
with a green gooey invader:


For many people living along the western edge of Lake Erie, seeing
algae is nothing new. Lake Erie is the shallowest and warmest of the
five Great Lakes. Algae like to grow here. But the cold winter months
usually kill off what grows over the summer.


(Sound of lake)


That’s not the case for a new type of algae that has spread through
this area in the last year. Jerry Brown has lived and paddled his
boats along these shores for years. We’re standing next to a beach
that is piled with mounds of dried green and brown algae three feet
high:


“It’s like a carpeting that grows on top of itself and becomes matted –
and it appears to dry but it doesn’t deteriorate. What used to be my
wonderful seafront, and waves lapping up against my seawall, is now
what I call my lower forty because it’s a field.”


The algae are known as Lyngbya wollei. Residents have been
warned not to touch it because it might cause skin rashes.
Lyngbya algae are common in Florida and some other southern
states. It probably hitched a ride up here from a pleasure boat.


(Sound of tractor)


Just down the road Brown’s neighbor is John Pastorek. He’s using his
tractor to lift a water pump out of the Lake. He uses the pump to water
the lawns around his house. Recently, his pump stopped working. It’s completely
covered by the dark green goop:


“And so the pump can’t suck through that. So now I’ve gotta clean
that off of here so that the filter can once again work. But it’s a short
term solution because it’s going to fill back up again.”


Pastorek says he’d love to find a way to get rid of the algae. What
he’s not aware of is that he might be contributing to the problem.
His house is surrounded by green lawns:


“You know my wife and daughter just returned from Ireland and yesterday
they said, ‘Boy, this looks just like Ireland. It’s so green.'”


It’s that green because it gets treated with fertilizers by a lawn care
company. The invasive algae feed on fertilizers that are washed off
the land by rain. I’m here with Sandy Binh of the environmental group
the Waterkeeper Alliance. She’s also Pastorek’s neighbor.
And she tries to convince him to tell his lawn company to stop using
phosphorus as a fertilizer:


“It will be just as green. It will not change it a bit. In fact
Lowe’s now on their Scott’s products that they sell – there’s no
phosphorus. I checked this year. A lot of companies are adopting it because they know it’s not needed. It can actually have less cost because they don’t have to put that in it. It doesn’t have any effect on your
lawn – there’s no reason to have it.”


Binh says to stop the invasive algae – one of the most important things
people can do – is to stop giving it nutrients such as phosphorus.
These nutrients come from a lot of places. They leak from septic
systems. They come from sewage treatment plants. And they wash off
farm fields and lawns:


“We really need to get it out of dishwasher detergent, to get it out
of lawn fertilizers, to work with the agricultural community to reduce
it. We need to find out what’s causing it quickly because we don’t
want to become the old poster child where Lake Erie is really having major
problems.”


Researchers say phosphorus isn’t the only problem. They say people
need to cut back on on another of the algae’s favorite food – nitrogen.
Hans Paerl is with the Institute of Marine Sciences in North Carolina.
He says once these mats of algae get started – it can be tough to stop
them, because they can start to make their own nutrients:


“In many ways – once that bloom gets going it becomes a sort of self-
fulfilling prophecy. The bottom line is we need to think about
nitrogen as well as phosphorus as far as ultimately controlling and managing these blooms.”


(Sound of lake)


Back at the lakefront, boater Jerry Brown says he hopes they can solve
the problem soon:


“You now, I’m seventy years old. I’ve been here 40 years. I love
living on the lake and I no longer have any use for the lake. I’m very fearful that this won’t be corrected and
that I’ll end my days not being to use the lake that I love so much.”


To stop the spread of these kinds of algae it will take cooperation
from farmers, cities… pretty much everyone. Anything we put on the
land or in our pipes flows into the water. But at the moment, most
people don’t seem to know that they’re a part of the problem and
nutrients such as phosphorus and nitrogen continue to pollute the
water.


For the Environment Report, I’m Mark Brush.

Related Links

Bird and Fish Poisoning Spreads in Great Lakes

  • Botulism is killing fish and the shorebirds that eat them. The cause is likely due to a disruption in the ecosystem by invasive zebra and quagga mussels. (Photo by Lester Graham)

A deadly toxin is killing fish and birds along the Great Lakes shoreline.
Researchers think type-E botulism works its way up the food chain from
the bottom of the lake through several invasive species. Bob Allen
reports:

Transcript

A deadly toxin is killing fish and birds along the Great Lakes shoreline.
Researchers think type-E botulism works its way up the food chain from
the bottom of the lake through several invasive species. Bob Allen
reports:


These days, Ken Hyde dreads walking the pristine sandy beaches along
the Sleeping Bear Dunes. He’s the biologist in this national lakeshore
along the Michigan coast, and he only has to hike maybe a hundred feet
to find a dead bird twisted head down and half-buried in the sand:


“This is a cormorant. Just in the last two or three weeks we’re
starting to see a lot more of them. So they’re probably starting to
migrate down from the upper parts of the lake.”



Last year botulism killed over 2,500 dead birds along this 35 mile stretch
of shoreline, mostly gulls and diving ducks, including nearly 200 loons
migrating south from Canada.


This year the die-offs started earlier in the summer and struck more
species. The park lost four endangered piping plovers. The National Park
Service brought in a research team from Minnesota to look for answers.
They’ve been diving in the lakeshore now for two years.


What they’ve found is a huge shoal stretching more than a mile off shore.
It’s covered with native green algae and loaded with invasive zebra and
quagga mussels:


The Park’s research boat docks at a small village along Lake Michigan.
Dive team leader Brenda Moraska Lafrancois was surprised when she
first saw the underwater landscape:


“Last year when we first dove this area we went down and it was
shocking how little of the biomass down there was native. I think
we’re looking at a really altered system.”


Here’s what researchers know so far. The mussels filter nutrients from
the water, the clearer water allows more sunlight to reach the bottom, and
that spurs more algae growth. For good measure, the mussels excrete
phosphorus, in effect fertilizing the algae in the near shore zone. When
millions of mussels and big globs of algae begin to decompose, that uses up
most of the oxygen in water near the bottom of the lake, and that’s a
condition just right for a naturally occurring botulism to grow.


So how does the botulism migrate from the bottom to the surface and
poison shorebirds? Enter the round goby. It’s a small invasive fish that
comes from the same Caspian Sea area where zebra mussels originated.


Last year the research team at Sleeping Bear saw gobies in some places.
Now, says Byron Carnes, everywhere they looked when diving on algae
beds there solid sheets of mussels and blankets of gobies, and he
watched them feeding on mussels:


“Part of the zebra quagga mussel that is the juiciest these guys tend
to go right in and do this frenzy feeding where they just come in and
start pounding away at all the broken shells and trying to get out as
much of the good stuff inside the quagga mussel as they possibly
can.”


Mussels don’t have a nervous system, so they aren’t harmed by botulism
toxin. But when gobies get a dose they flop around on the surface for a
day or so while succumbing, and that’s when shorebirds pick up an easy
but potentially deadly meal.


Some diving ducks may also get poisoned by feeding directly on the
mussels. That’s the theory most scientists in the field think explains
what’s happening, but Harvey Bootsma says it’s not active all the time, so
it’s hard to prove each step. He’s with the Great Lakes Water Institute in
Milwaukee:


“I think the problem is it’s usually a sporadic and short-lived event
when this occurs. And unless somebody happens to be fortuitously
collecting the right samples at the right place and the right time it”s
very difficult to pin down the process as it’s occurring.”



While researchers try to pin down the effects of invasive species in one
place, the cycle spins off somewhere else. This fall there are half as
many dead birds along the Sleeping Bear Dunes shore as last year, but
the die-off is now spreading farther north along the Lake Michigan coast,
and there have been similar outbreaks along Lakes Erie and Huron.


So far Harvey Bootsma says there are no good solutions to break the
cycle of algae, mussels and gobies that scientists think is transporting
botulism toxin to shorebirds.


“And it’s just a great example of how huge an impact a new species
can have on an ecosystem. And I think it makes it all the more
imperative that we try to stem the tide of exotic species coming into
the Great Lakes.”


Researchers say it may take decades for the Great Lakes to recover from
the effects, if they ever do.


For the Environment Report, I’m Bob Allen.

Related Links

Ethanol Part 2: Widening the Dead Zone?

  • Farmer Laura Krouse says the ethanol boom has been great for corn farmers, who she says are finally getting a fair price for their corn. But she says she's worried that there's not enough being done fast enough to reduce the dead zone in the Gulf of Mexico. (Photo by Rebecca Williams)

Scientists are predicting the Dead Zone in the Gulf of Mexico will reach its largest size ever this summer. Fish and shrimp can’t survive in the Dead Zone. It’s believed to be mainly caused by fertilizer washed from farm fields across the nation. Rebecca Williams reports some scientists say demand for ethanol made from corn could make the Dead Zone even bigger:

Transcript

Scientists are predicting the dead zone in the Gulf of Mexico will reach its largest size ever this summer. Fish and shrimp can’t survive in the dead zone. It’s believed to be mainly caused by fertilizer washed from farm fields across the nation. Rebecca Williams reports some scientists say demand for ethanol made from corn could make the dead zone even bigger:


(Sound of tractor raking hay)


“It’s the perfect Iowa day, you know?”


Laura Krouse is tearing apart a bale of hay to mulch her tomatoes.
She’s a thousand miles from the Gulf of Mexico. But she points out,
what happens on farms here ends up affecting life way down South:


“This watershed I live in drains 25% of Iowa. And we’re one of the
richest farming states in the nation – of course we have something to
do with it.”


By “it,” Krouse means the dead zone. All or parts of 31 farm states
drain into the Mississippi River, which empties into the Gulf.
Scientists point to nitrogen fertilizer used on farm fields as the main
cause of the dead zone. All that nitrogen causes an enormous algae
bloom. When the algae dies it drops to the ocean floor. Bacteria eat
the algae and they rob the water of oxygen.


This summer, the dead zone’s predicted to reach a record size. It could get as big as the state of New Jersey.


Laura Krouse has been trying to cut back her own role in the dead zone.
Five years ago, she added something to her farm that’s rare around here.
Krouse cut some of the tile lines that drain water from her farm, and
replaced part of her farmland with a prairie wetland. She says that
made her neighbors nervous:


“We just don’t see people taking land out of production in Iowa very
frequently.”


Wetlands like this one remove nitrogen from the water that flows from
farm fields.


It’s one of the things a government task force on the dead zone
recommended to cut nitrogen loading into the Gulf.


But instead of a big push to restore wetlands, the economic landscape
is changing in the other direction. Demand for ethanol has led to
historically high corn prices. And that’s encouraging farmers to grow
more corn. A USDA report says farmers have planted 14 million more
acres of corn this year than last year. It’s the most corn planted in
the U.S. in more than 50 years.


Laura Krouse says this is not good for the Gulf of Mexico:


“I’m concerned about all the extra corn because it requires nitrogen to
produce that corn and no matter how careful we are and no matter how
expensive it is which causes us to be more and more careful with
application, nitrogen as a molecule just wants to get away. It is
leaky.”


When it rains, nitrogen runs quickly from farm fields and gets into
creeks and rivers. The federal government’s task force on the dead zone has been trying to
tackle all this.


Don Scavia led a group of scientists advising the task force under the
Clinton Administration. The Bush Administration convened a new science
panel to review the original science panel’s work. Don Scavia says
since then, there’s been very little progress in shrinking the dead
zone, or what scientists call an area of hypoxia:


“In fact what we’ve seen in the last year is just the opposite with
this push towards corn-based ethanol production. Even acres that were
set aside into conservation are coming back out into production, into
corn, and the increased nitrogen load to the Gulf this year and the projected record
hypoxia is probably caused by this increased corn production.”


Scavia says if the dead zone keeps increasing, the Gulf shrimping
industry could collapse.


Ironically, the new science panel appointed by the Bush White House is
calling for even bigger cuts in nitrogen than the first panel appointed
by the Clinton Administration. They want to reduce nitrogen from farm
fields and other sources by 40 to 45 percent.


Don Parrish is with the American Farm Bureau. He says those reductions
are too much:


“Those are going to be really difficult and they could cause
significant economic dislocation at a time when I think we need to be
thinking about the products that agriculture produces, and those are
important.”


There’s no question corn for ethanol is at the top of that list right
now. Ethanol’s popular. It’s making farmers richer. It’s making the
chemical companies that supply nitrogen richer. The government task
force has to figure out how to cut back on all the nitrogen that’s
needed to grow all the corn… that’s needed for billions of gallons of
ethanol.


For the Environment Report, I’m Rebecca Williams.

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Toxin Kills Endangered Birds

  • A poisoned seagull on a Lake Erie Beach. Type-E botulism is spreading up the food chain and killing birds on the endangered species list. (Photo by Lester Graham)

A toxin that has killed tens of thousands of shorebirds throughout
the Great Lakes is back. Type-E botulism is spread up the food
chain by invasive species. And as Bob Allen reports, the toxin
recently killed four birds on the endangered species list:

Transcript

A toxin that has killed tens of thousands of shorebirds throughout
the Great Lakes is back. Type E botulism is spread up the food
chain by invasive species. And as Bob Allen reports, the toxin
recently killed four birds on the endangered species list:


There are just 60 pairs of piping plovers known in the Great
Lakes. Many of them breed along the shores of Lake Michigan.


Wildlife officials protect nesting plovers by putting up fences to
keep predators away, but they can’t keep the tiny shorebirds from
eating insects as they skitter up and down the beach. The insects
can pass on Type E botulism to the endangered birds.


Biologist Ken Hyde says the toxin gets into the food chain
through fish – primarily round gobies – that feed on algae and the
invasive zebra and quagga mussels.


“Yeah, we’ve got some pretty good evidence that it’s this cycle of
the algae and then the mussels and the gobies feeding on them
and then primarily gobies coming to the surface that our native
water birds are feeding on.”


Wildlife officials expect to see a lot more dead shorebirds as
the summer progresses.


Type E botulism is not a threat to humans.


For the Environment Report, I’m Bob Allen.

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Searching for New Bio-Diesel Source

The U.S. is looking for ways to depend less on foreign oil and reduce greenhouse
gas emissions. A popular method is so-called bio-fuels. Those are fuels, such as
ethanol or bio-diesel, made from plants. Cleaner burning bio-diesel has been billed
as an environmentally-friendly replacement for our 60 billion gallon a year thirst for
diesel oil. But there aren’t enough crops or land to produce enough bio-diesel to
replace fossil fuel-based diesel. Amy Quinton reports new research is looking at
another way to make bio-diesel: using algae:

Transcript

The U.S. is looking for ways to depend less on foreign oil and reduce greenhouse
gas emissions. A popular method is so-called bio-fuels. Those are fuels, such as
ethanol or bio-diesel, made from plants. Cleaner burning bio-diesel has been billed
as an environmentally-friendly replacement for our 60 billion gallon a year thirst for
diesel oil. But there aren’t enough crops or land to produce enough bio-diesel to
replace fossil fuel-based diesel. Amy Quinton reports new research is looking at
another way to make bio-diesel: using algae:


Bio-diesel is made primarily from plant oils: soybean, canola, rapeseed. Ihab Farag
is a chemical engineering professor at the University of New Hampshire. He climbs
up scaffolding to demonstrate a processor that turns waste oil from the University’s
cafeteria into bio-diesel. Farag says this is more environmentally-friendly than diesel:


“It’s coming from vegetable oil, so therefore it’s cleaner… it doesn’t have the sulfur in it so you
don’t get acid rain issue that you get from diesel, it doesn’t do particulates which are suspect[ed] to be cancer-
causing.”


Almost any diesel engine built in the last 15 years can use bio-diesel, but Farag says
there’s a major drawback: it takes an acre of most crops to produce only 100 gallons
of bio-diesel per year:


“I think it has been estimated that if we are using just something like soybean[s] and want to
produce bio-diesel for the whole country, we need almost an area of land that’s about
two and a half to three times the area of Texas.”


That would be an environmental nightmare because bio-fuels require a lot of fossil
fuels to plant, harvest and process them. They only produce a bit more energy than
the energy needed to make them. It also would put the nation’s fuel needs in conflict
with its food needs. That could drive the price of both sky-high.


So Farag and Master Chemical Engineering student Justin Ferrentino are looking at
another plant. One that’s capable of producing much more oil : algae.
Inside the University’s bio-diesel lab, Ferrentino holds up a glass jar filled with a sea-
green powder:


“This is freeze-dried cells that we’ve grown up in our photo-bioreactor.”


He’s testing different ways of extracting oil from these single-celled algae plants to
produce the most bio-diesel:


“People have projected with micro-algae you can grow somewhere between five and 15,000
gallons per acre per year, so it’s a big difference.”


Compared to 100 gallons per acre of soybeans, it’s a very big difference. Ferrentino
has built a contraption of two small fiberglass tanks, surrounded by florescent lights
and reflectors. It’s called a photo-bioreactor. With the right amount of light, the algae
here grows rapidly:


“When I fill these with growth medium and then add the cells to them and they just
multiply, they divide… they double every ten to 15 hours, when they’re growing
exponentially.”


The more cells, the more oil, and the more bio-diesel. Ferrentino’s photo-bioreactor
is small, producing only a tenth of a gram of bio-diesel. But build one on a larger
scale where there’s lots of sunlight, like the desert Southwest, and it could potentially
produce thousands of gallons on just an acre of land.


And Farag says because carbon is needed to fertilize algae growth, the potential
exists to remove greenhouse gases while simultaneously producing bio-diesel:


“If we can connect it with a wastewater treatment plant, where they have a lot of
waste coming in with lots of carbon in it then you can consume the carbon to grow
the algae and at the same time clean up the wastewater.”


But skeptics say one of the biggest challenges is making algae production
economical. Commercial production would initially yield fuel that could cost between
20 and 50 dollars a gallon. Ferrentino recognizes the drawbacks, but says their
research is worth pursuing:


“I think that our energy needs are not necessarily going to be solved with a magic
bullet, but I think this is certainly one part of it, being that you don’t need arable land
you have the added benefit of maybe being able to use the carbon from flue gases
from power plants, maybe being able to treat wastewater. So, it has some significant
added benefits so it could be one piece of the energy picture.”


But growing algae in the desert or anywhere else doesn’t have the kind of political
appeal that subsidizing farmers to grow soybeans for soy-diesel does. So finding
funding for a commercial-sized algae bio-reactor will face significant obstacles.


For the Environment Report, I’m Amy Quinton.

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