Monday, April 13, 2009
KIDS CONNECT - AT SHOW SEARCH ENGINE
LATEST AND GREATEST THINGS HAPPENING IN THE SUSTAINABLE GREEN INDUSTRY, AUTO, WATER, EDUCATION, AGRICULTURE,TOURISM, ALTERNATIVE ENERGY INFRASTRUCTURE.
10 Big Questions for Maverick Geneticist J. Craig Venter on America's Energy Future
uly 30, 2008
EmailEmail Print RSS 2.0
Buzz up!
Buzz up!
this story
ALSO SEE...
* Railroad Stimulus: How to Spend $14 Billion to Improve U.S. Rail
* Up Close With Ocean Cores: JOIDES Scientists Put the Seabed Under the Microscope
* Lost Channels Ancient Egyptian Legend to Explain Smoke Monster
* The Future of Needles: Upgrading Medicine's Most-Used Tool
* Where are they Now? 9 Auto X Prize Team Updates
See more...
Section Archive
KEYWORDS
* Questions for
* biofuel
* genetics
* alternative energy
* research
* Barack Obama
* John McCain
10 Big Questions for Maverick Geneticist J. Craig Venter on America's Energy Future
J. Craig Venter
(Photograph by Michael Nagle/Getty Images)
Independent geneticist J. Craig Venter raced an international consortium of scientists to map the human genome in the 1990s. Now he's putting the same cutting-edge science to work on today's energy crisis, engineering a whole new generation of biofuels. In a rare in-depth interview, we talked to Venter recently about his latest project to save the world, as well as historical flubs, today's presidential candidates and the future of genetics. —Chris Ladd
So how did you get from mapping the human genome to creating biofuels?
We considered the biggest issues facing society that we thought we could impact. What's happening to the environment and getting weaned off oil and coal are the biggest issues out there.
Is it similar to the genome project? More daunting?
Nobody thought that such a massive project as sequencing the human genome could be undertaken by a single team, like we did. But that challenge is minor compared to trying to replace the 30 billion barrels of oil that we use globally each year, and the 3 billion tons of coal. The scale of that is beyond my imagination.
I think the real challenge won't necessarily come from biology, because biology is infinitely scalable, but from engineering. [If we can overcome that,] we have the potential to stop using oil and coal hopefully within the next 10 to 20 years, and even start reducing the CO2 concentrations in the atmosphere.
How do you plan to do that?
We're working on what we call second-, third- and fourth-generation fuels. Like corn-based ethanol, a first-generation biofuel, our second- and third-generation fuels start with sugar as the feedstock. But unlike it, we're making fuels that have very high energy content, don't mix with water and have very low freezing points—well under 100 degrees below centigrade. They have the potential of working in high-altitude aircraft.
And the fourth-generation fuels?
We're using a unique type of algae that we've genetically engineered to turn sunlight and CO2 into C8 and C10 and larger lipids. The people that initially grew algae viewed it as farming—you know, you grow a bunch of algae and then you harvest it. But it's totally different if the algae are chemical factories. Ours continuously secrete these molecules, so we get constant production of something that can basically be used right away as biodiesel.
So they perform better than traditional biofuels—but will they actually be better for the environment?
Because we actually have to feed them concentrated CO2, we can take CO2 streams from power plants, cement plants and other places. People view CO2 as a contaminant—they want to bury it in the ground or pump it into wells to hide or sequester it. We want to take all that waste product and convert it into fuel.
When do you hope to have these fuels in people's cars?
Our goal is to have multiple things on the market within five years. We're looking now at how to scale this up. Our molecules are much higher energy density [than ethanol], but even so we need to produce hundreds of billions of gallons if we're really going to make a dent in oil use.
This is national security. We seem to be fighting wars at least in part over oil, we're sending most of our money to the Middle East and other places, and we're investing as a nation almost nothing in alternatives.
Since the 1970s oil crisis, a number of policies have been enacted to increase energy independence. Do you think they've been effective?
Had we followed intellectually where we were back in the Carter era, we wouldn't have a lot of the problems we do today. We've had a lot of short-term thinking from administrations that basically trades off the health of the planet for economic gain for the business community—and for their own re-election. We don't reward our leaders for making long-term beneficial decisions for society. It's like the stock market—all that matters is the next quarter, not where you are 10 years from now.
Do you think there's potential for change with the current presidential candidates?
I think either candidate would be orders of magnitude better than what we had in this administration, but I think Obama would be a few orders of magnitude better than McCain. Although McCain has been a longtime supporter of changes in the CAFE standards—trying to get higher-mileage cars—and has consistently been shouted down by his colleagues.
What about McCain's recent pledge to offer a $300 million prize for a better electric car battery?
Industry is very motivated to make new batteries. Whoever makes a better battery is going to make a fortune, and having a government incentive to do that doesn't necessarily move it along. In fact, if it's like the human genome project, it could just slow it down.
Where do you see the science of genetics going in the near future?
I see it as parallel to the electronics industry in the 1940s and '50s, a stage when all of the things that enabled computers came out of just a few handfuls of components—resistors, transistors, capacitors—and people were pretty much limited only by their imagination. My team has discovered more than 20 million new genes, so we're in a biological universe. There are no fundamental limits. I think we're going to see the next 25 years as some of the most innovative in the history of science.
Subscribe to:
Posts (Atom)