On the heels of his ASU KEDtalk, Klaus Lackner explains his process, shares his inspiration and discusses the challenges involved in making carbon air capture a reality.
By Kelsey Wharton
Nov. 16, 2017
Klaus Lackner is concerned. And he thinks you should be, too.
The concern of the ASU professor and founding director of the Center for Negative Carbon Emissions is simple: there’s too much carbon dioxide in the atmosphere. The proposed solutions, like capping carbon emissions, tend to focus on slowing the rate at which we pump out carbon dioxide. Lackner has another idea.
He has developed technology that captures carbon dioxide from the air at rates much faster than trees and plants. What’s more, this technology could be mass produced and deployed worldwide.
On the heels of his ASU KEDtalk presentation, Lackner talked with Knowledge Enterprise Development writer Kelsey Wharton about the inspiration for his elegant technology, the challenges to advancing it on a large-scale and how everyone can help make it happen.
Take a look inside Klaus Lackner's ASU lab as he explains how his carbon air capture technology works.
Did you have a eureka moment in developing carbon air capture or was it a slower evolution of ideas?
Both. The eureka moment happened when I looked at devices which were passing air in order to run wind turbines.
It struck me that if they instead scrubbed CO2, they would have a much larger impact on the carbon footprint than they had from making energy. Energy allows you to reduce the CO2 footprint because you displace fossil energy. Scrubbing it out allows you to remove CO2 which already came out, so you also reduce the footprint.
This made me ask the question, "How much CO2 is actually in the air compared to how much energy is in the air as wind energy?" And I found there's far more CO2.
I said, “This has got to work.” Because contacting the air is obviously easier than it is for a windmill. The windmill contacts the air in order to remove kinetic energy, and I need to contact the air to remove CO2. To have the same impact, I can be a hundred times smaller than a windmill. That was the “aha” moment.
I found out, though, when I look back, I wrote a paper five years earlier where we talked about the possibility of doing this, but we didn't go deeper into it then.
Sometimes those things kind of need to simmer.
Yes, there's a slow part with this, too. I clearly had thought about it before because we wrote a paper where we said, "If you really needed to, we could get the CO2 back out of the atmosphere." Then five years later I wrote a little conference paper where we said, "It's actually an option. We should think about it seriously." That's when I started.
What challenges or failures have you experienced along the way to creating CO2 air capture technology?
There are different kinds. There are the technical ones. There's also a bigger challenge that people said it’s just impossible: "You're wasting your time. This is not working. Forget it." People said it's thermodynamically not possible. No, it’s thermodynamically quite possible, and here's the paper that says so. Now they say, "It's just very difficult."
I sort of relate that [sentiment] to air flight. People were also very sure that it couldn’t be done. I have an analogy there, too, because you could look out of a window – you don't see any right now, but there are birds flying. They clearly are heavier than air and they clearly fly, so yes, it is possible. You look out of this room you see plenty of trees, so it's clearly possible to capture CO2 out of the air, you just have to do it the right way.
The other part, which is still a serious obstacle to this day, is that there are two groups I have to convince. One is the climate skeptics. "Why in the world would you want to solve a problem that doesn't exist?" They're at least consistent, even though it's nonsense that climate change doesn't exist.
Then there's also a strong environmental voice which basically says, "If you do that, then people won't change their lifestyle."
That actually makes it hard to get this type of work funded. It's hard to make this kind of work move forward. As a consequence, when we really need it, it's probably not ready yet. That's where the obstacles are.
Some formidable ones.
Some formidable ones, but I think eventually that obstacle will fall by the wayside because physics has a nasty habit, nature has a nasty habit of asserting itself.
The biggest challenge actually is overcoming that which people call a "moral hazard." I think it's fundamentally wrong. We answered this in a Science letter, where I said, "Somebody is about to drown and you throw a life preserver and you're not going to argue that throwing a life preserver may prevent people from learning how to swim."
The other thing I say, we're in a car coming up at a sharp curve and we're going to hit the guard rail. There's no question in my mind that we will. Now the question is, will we roll over or will we just have a nasty scrape in the fender? To argue, "Don't touch the brake!" may not be the right way to think about the problem.
At this point we need to do everything we can. It's also worth keeping in mind, if we overshoot, there will be irreparable damage. I don't think we can avoid that anymore. At this point, the question is having to minimize the irreparable damage.
If a person or a foundation came to you today and said, "We're ready to invest $100 million in this," what would you be able to do?
I would pull together a team to make this work, to make air capture work in multiple flavors and start creating negative emissions people would buy. I think, for that amount of money, you can do that. I think it would take two or three years to make one or two versions of the technology work, and you then would be at a starting gate to really pull this out.
With this kind of support, you can get the engineers and also the people who can put all the other things around it to turn it into something that works. I am confident that at that level, you could do it.
For people who want to see this technology developed on a large scale but don't have $100 million lying around to invest, what can they do?
Ask for a button on the [gas] pump [to buy carbon offsets]. That will drive the technology. That would allow you to buy renewable energy. You should get to the point where you say, "I clean up the CO2 I produce. If I fly somewhere, I'll buy the offset."
By the way, I would make sure it's the real offset, and I would not count saying we improved the efficiency of a power plant, or a coal plant, and therefore we have created a carbon credit.
That's why I think once this becomes real, an important ingredient in the story – and that's the part where the $100 million would go – is to actually truly create a certification mechanism which says, "I can assure you that carbon has indeed been put away, and this is how it has been done." This is fair and square and it's not a gimmick where we make it look like we've reduced CO2 emissions.
Is there one particular challenge or barrier that is the standing in the way of this becoming a widespread technology?
Cost. That's a fundamental problem with new technologies. They always start expensive and then become cheap. In the high‑tech computer side, you get away with it because you have initial applications for which the high price is okay.
I'm thinking now of an old CD‑ROM. The first one I bought, I spent probably $20 on this little disk, but it was worth it because I suddenly could store 600 megabytes of data on a little thing I could leave in my drawer and come back a year later and it would still be there. This was powerful.
Eventually, they came down to $10, then 10 cents. But nobody could really predict that at the beginning, except once you start mass producing, you come running down this curve. But it is important that somebody at the beginning said, "I have no trouble spending $20."
I also think it has to come from the grassroots. I think we have to convince people to clean up after themselves. That's that waste management story I talked about [in my ASU KEDtalk]. There’s no better way of manifesting that than by saying, "I'm doing it."
The Center for Negative Carbon Emissions is partially supported by Arizona’s Technology and Research Initiative Fund. TRIF investment has enabled thousands of scientific discoveries, over 800 patents, 280 new startup companies and hands-on training for approximately 33,000 students across Arizona’s universities. Publicly supported through voter approval, TRIF is an essential resource for growing Arizona’s economy and providing opportunities for Arizona residents to work, learn and thrive.