Who sends out press releases on a Sunday? UCLA does when the content is expected to match Obama’s draconian climate announcement planned for Monday.
Reducing emissions will be the primary way to fight climate change, UCLA-led study finds
A new report by professors from UCLA and five other universities concludes that there’s no way around it: We have to cut down the amount of carbon being released into the atmosphere. The interdisciplinary team looked at a range of possible approaches to dissipating greenhouse gases and reducing warming.
Forget about positioning giant mirrors in space to reduce the amount of sunlight being trapped in the earth’s atmosphere or seeding clouds to reduce the amount of light entering earth’s atmosphere. Those approaches to climate engineering aren’t likely to be effective or practical in slowing global warming.
“We found that climate engineering doesn’t offer a perfect option,” said Daniela Cusack, the study’s lead author and an assistant professor of geography in UCLA’s College of Letters and Science. “The perfect option is reducing emissions. We have to cut down the amount of emissions we’re putting into the atmosphere if, in the future, we want to have anything like the Earth we have now.”
Still, the study concluded, some approaches to climate engineering are more promising than others, and they should be used to augment efforts to reduce the 9 gigatons of carbon dioxide being released each year by human activity. (A gigaton is 1 billion tons.)
The first scholarly attempt to rank a wide range of approaches to minimizing climate change in terms of their feasibility, cost-effectiveness, risk, public acceptance, governability and ethics, the study appears in the latest issue of the peer-reviewed scholarly journal Frontiers in Ecology and the Environment.
The authors hope the information will help the public and decision-makers invest in the approaches with the largest payoffs and the fewest disadvantages. At stake, the study emphasizes, are the futures of food production, our climate and water security.
Cusack, an authority on forest and soil ecology, teamed up with experts in oceanography, political science, sociology, economics and ethics. Working under the auspices of the National Science Foundation, the team spent two years evaluating more than 100 studies that addressed the various implications of climate engineering and their anticipated effects on greenhouse gases.
Ultimately, the group focused its investigation on the five strategies that appear to hold the most promise: reducing emissions, sequestering carbon through biological means on land and in the ocean, storing carbon dioxide in a liquefied form in underground geological formations and wells, increasing the Earth’s cloud cover and solar reflection.
Of those approaches, none came close to reducing emissions as much as conservation, increased energy efficiency and low-carbon fuels would. Technology that is already available could reduce the amount of carbon being added to the atmosphere by some 7 gigatons per year, the team found.
“We have the technology, and we know how to do it,” Cusack said. “It’s just that there doesn’t seem to be political support for reducing emissions.”
Of the five options the group evaluated, sequestering carbon through biological means — or converting atmospheric carbon into solid sources of carbon like plants — holds the most promise. One source, curbing the destruction of forests and promoting growth of new forests, could tie up as much as 1.3 gigatons of carbon in plant material annually, the team calculated. Deforestation now is responsible for adding 1 gigaton of carbon each year to the atmosphere.
Improving soil management is another biological means of carbon sequestration that holds considerable promise because soils can trap plant materials that have already converted atmospheric carbon dioxide into a solid form as well as any carbon dioxide that the solids give off as they decompose. Since the dawn of agriculture, tilling land has led to the loss of about half (55 to 78 gigatons) of the carbon ever sequestered in soil, the team reports. But such simple steps as leaving slash — the plant waste left over after crop production — on fields after harvests, so it could be incorporated into the soil, could reintroduce between 0.4 and 1.1 gigatons of carbon annually to soil, the study says. The approach would also improve soil’s ability to retain nutrients and water, making it beneficial for additional reasons.
“Improved soil management is not very controversial,” Cusack said. “It’s just a matter of supporting farmers to do it.”
The study also advocates a less familiar form of biological sequestration: the burial of biochar. The process, which uses high temperatures and high pressure to turn plants into charcoal, releases little carbon dioxide into the atmosphere. Under normal conditions, decaying plant life inevitably decomposes, a process that releases carbon dioxide into the atmosphere. But charred plant material takes significantly longer — sometimes centuries — to decompose. So the approach can work to keep carbon that has become bound up in plant life from decaying and respiring as carbon dioxide. And like working slash into the soil, adding biochar to soil can improve its fertility and water retention.
“Charcoal has been used as an agricultural amendment for centuries, but scientists are only now starting to appreciate its potential for tying up greenhouse gases,” Cusack said.
But not all biological sequestration would be so beneficial. The researchers evaluated the idea of adding iron to oceans in order to stimulate the growth of algae, which sequesters carbon. The approach ranked as the study’s least viable strategy, in part because less than a quarter of the algae could be expected to eventually sink to the bottom of the ocean, which would be the only way that carbon would be sequestered for a long period of time. The study predicted that the rest would be expected to be consumed by other sea life that respire carbon dioxide, which would end up back in the atmosphere. Additionally, increasing the algae blooms would likely wreak havoc by decreasing the oxygen available for other marine life.
The study’s second most promising climate engineering strategy, after carbon sequestration, was carbon capture and storage, particularly when the technique is used near where fuels are being refined. CCS turns carbon dioxide into a liquid form of carbon, which oil and coal extraction companies then pump into underground geological formations and wells and cap; millions of tons of carbon are already being stored this way each year. And the approach has the potential to store more than 1 gigaton permanently each year — and up to 546 gigatons of carbon over time — the study says.
However, a liquid carbon leak could be fatal to humans and other animals, and the risk – while minimal – may stand in the way of public acceptance.
“With CCS we’re taking advantage of an approach that already exists, and big companies pay for the work out of their own pockets,” Cusack said. “The hurdle is public perception. No one wants to live next to a huge underground pool of carbon dioxide that might suffocate them and their children – no matter how small the risk.”
Reducing the amount of sunlight that is heating up the atmosphere through measures such as artificially increasing the earth’s cloud cover or putting reflectors in outer space ranked as the study’s second least viable approach. While cloud seeding is cheap and potentially as effective as improving forestry practices, the approach and its potential impacts are not well enough understood for widespread use, the team concluded.
“Cloud seeding sounds simple,” Cusack said. “But we really don’t understand what would happen to the climate if we started making more clouds.”
Cusack’s collaborators were Jonn Axsen, assistant professor of resource and environmental management at Simon Fraser University in British Columbia, Canada; Lauren Hartzell-Nichols, acting assistant professor in the program on values in society and the program on environment at the University of Washington; Katherine Mackey, a postdoctoral researcher at Woods Hole Oceanographic Institution and the Marine Biological Laboratory in Woods Hole, Mass.; Rachael Shwom, assistant professor in human ecology at Rutgers University; and Sam White, assistant professor of environmental history at Ohio State University.
firmly, those universities want to fill every seat in our ever growing university campuses. With greed in their eyes and salivation at the thought of all those incoming freshman, they understand that it does not matter if they all graduate or that they will provide an intelligent and thoughtful approach to their subsequent years. The first year’s tuition is another building as far as they are concerned. Who cares about the outcome. Unfortunately that has meant that we have many overeducated people who should not have gone to university in the first place! It is my opinion that several climate scientists are aptly described as such. They clearly lack an intelligent and thoughtful approach to their endeavors and instead simply wring the sh** out of the grant gravy train. Whatever it is.
“The Gods are angry. The High Priests tell the people what they must sacrifice in order to placate The Gods.”
“Skyonics also support a price on CO2 (carbon emissions trading/cap and trade)”.
They also say on their website, “when it is free for polluters to emit CO2, most carbon capture companies are struggling for business.”
Richard Sharpe says:
June 1, 2014 at 10:24 am
CO2 is pollution in quantities approaching 5,000ppm, as far as I am aware, and we already have a great system of CO2 capture. It’s called plants.
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One way to understand mankind’s contribution to atmospheric CO2 is to equate a dollar value to a quantity of air. For instance, $10,000 of air would contain 1 penny of man’s CO2 emissions.
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Pamela Gray says:
June 1, 2014 at 10:30 am
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Pamela, by your logic, you have just made an argument which could be extended against all of agriculture.
“The best is the enemy of the good”–ever heard that one, Ms. Cusack?
I couldn’t find those on their web site.
Yes, it could. Then again, it might not. So why not try it out on a small scale and see? If it does cause problems, it’s not irreversible — we’d only have to stop and the recovery would be rapid.
We agree. So far so good — consensus intact.
Darn, they went and spoiled it. In engineering there is never a perfect solution — there are only choices among imperfect trade-offs. If you want more of desirable quality X, you have to be willing to part with some of desirable quality Y, or accept more of undesirable quality Z.
You can’t demand a reduction in human CO2 emissions without acknowledging and quantifying the possible trade-offs to achieve that goal. The usually unstated assumption is it will be sufficient to spend enough of other people’s money on research and
subsidiesmarket incentives.Alan? We already have a carbon cycle in place. More CO2 encourages more plants in our undeveloped land. So I don’t get your point. Agriculture is also a natural response to the supply and demand for food. No need to plant for the purpose of CO2 reduction. Natural processes do that for us.
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Here in the USA fireworks are the traditional way to celebrate our liberty on the 4th of July.
I guess both of those are out now.
If there is a concern about stifling algal blooms, then just disperse the iron dust less densely–perhaps by “dusting” it over a wide area from an airplane.
roger, you do understand the ratio: tiny airplane versus expansive ocean. Yes? The cost of seeding that would result in significant CO2 intake would be astronomically huge. And the CO2 belched out by the airplane under a financially viable program would make it a wash.
Iron seeding is beyond silly.
They are making “climate change” an election issue. Here in NC the senate seat is held by a backer of the president’s failed energy policy that wants to shut down all coal burning power plants.
Her challenger is arguing that climate has always been changing and trying to control CO2 by shutting down power plants will harm our states economy and put more people out of work. Who do you think an informed public will believe and vote for? Are they riding a dead horse?
Richard Sharpe says:
June 1, 2014 at 11:08 am
Skyonics also support a price on CO2 (carbon emissions trading/cap and trade)”.
They also say on their website, “when it is free for polluters to emit CO2, most carbon capture companies are struggling for business.
From the web address: http://skyonic.com/. On the main page, under the heading, “who we are”, there is a short video(3:53) entitled, “How to profit from CO2 emissions”. In the video the company talks about its business. The quotes above are from that video.
Obama’s Push may have the unintended side-effect of (finally) causing a pushback by alarmed scientists who have kept their heads down until now. The ranks are already breaking—Botkin, Tol, Benggston, and Stavins (on 4/26).
Richard Sharpe says:
June 1, 2014 at 10:24 am
According to this reference, human physiological tolernace to CO2 concentrations of 1.0% (10,000 PPM) is “indefinite”.
You exhale air with about 4% CO2, or 40,000 PPM. That air is breathable and will sustain human metabolism, which is why mouth-to-mouth resuscitation works. Humans begin to experience problems (“Headache, dyspnea upon mild exertion”) after 2 or more hours breathing CO2 at 2% (20,000 PPM) and will generally lose consciousness at 7-10%.
Ahhh, OK. I wonder if there is a transcript.
OK, so try it out first in a location where there aren’t any blooms or much of a food chain, AFAIK, like the Gulf of Alaska. Then monitor the site intensely for untoward consequences.
It’s been done already. The effect disappeared rapidly, which when considered, would greatly increase the cost of such a project to make it viable. I’ll see if I can find the article.
What then is this “Carbon Pollution”?
A sinister, evil collusion?
CO2, it is clean,
Makes for growth, makes it green,
A transfer of wealth, a solution.
http://lenbilen.com/2014/02/22/co2-the-life-giving-gas-not-carbon-pollution-a-limerick-and-explanation/
Thank you for improving my knowledge and you used their own data, as well.
Better save that document. I am sure they will remove it soon.
There are many papers out there. I like this one because it reviews the status of the theory. Even though it was submitted in the later 90’s much of what it said still holds true.
http://www.google.com/url?sa=t&rct=j&q=&esrc=s&source=web&cd=3&cad=rja&uact=8&ved=0CDsQFjAC&url=http%3A%2F%2Fwww.aslo.org%2Flo%2Ftoc%2Fvol_40%2Fissue_7%2F1336.pdf&ei=o3mLU9qONI62yASUrYK4Cw&usg=AFQjCNHy65NjWx7zIvmNVRxYU6HSSYWAvQ&bvm=bv.67720277,d.aWw
A faux solution in search of a nonexistent problem.
Pamela Gray: Iron seeding could disrupt the oscillation that has developed in algae bloom events. Other species in the food chain have adapted to this oscillation, which has taken hundreds of years to develop. These oscillations also slowly change on their own in response to our slowly changing planet. To disrupt this process by artificially injected an instantaneous speeding up, if you will, of this oscillation, would have severe consequences in my opinion. The small change in CO2 does not justify the risk we take on related to these unknown consequences.
I don’t know if that response was aimed at me, but it missed my two main points, so I’ll repeat them:(1) iron seeding has a proven track record, having increased primary productivity of algae everywhere it has been tried; (2) one of its proven effects is increasing yields from fisheries in the N.E. Pacific. CO2 reduction is neither tried and true, nor has it got any other benefit to help balance its cost; and it could potentially reduce primary productivity.
Pamela Gray: It’s been done already. The effect disappeared rapidly,
That is another way that it is like the use of manufactured fertilizer: you have to apply it regularly.