Geoengineering, la solución?

En agosto 2008 se publicó en Physics Today un artículo sobre geoengineering (ver abajo). Este artículo resultó en dos comentarios interesantes, que turnan alrededor de los posibles efectos secundarios indeseados y el aspecto ético que implica el posible "descuido" en la producción de CO2, ya que se tiene una remediación futura a la mano. Estos comentarios se publicaron en febrero 2009 en Physics Today y estan anexos al articulo abajo.

Will desperate climates call for desperate geoengineering measures?

Earth scientists ponder the wisdom of large-scale efforts to counter global warming.

August 2008, page 26

The public is finally paying attention to anthropogenic climate change, but it has not yet kicked its carbon habit. Global emissions of carbon dioxide continue to rise, with output in recent years exceeding the worst-case projections of just a few years ago. At the same time, Earth is showing signs of accelerated warming, such as Arctic sea-ice melting and a shrinking Greenland ice sheet.

Concerned that Earth's climate will change to an unacceptable degree or at an unacceptable rate before economies can shift significantly away from carbon-based energy sources, some scientists have begun casting their eyes in a previously shunned direction: geoengineering, or intentional and large-scale intervention to prevent or slow changes in the climate system.

Geoengineering sometimes refers strictly to techniques for increasing Earth's albedo, or reflectivity, to lower its temperature and compensate for greenhouse warming. More broadly, the term can include efforts to accelerate some of the natural processes for removal of CO₂ from the atmosphere. Many such ideas have been around for decades. In the past few years, however, the debate over their potential deployment has intensified.¹

Extreme measures?

The idea of deliberately tampering with Earth's climate system raises the specter of unintended consequences, especially because the interventions would be imposed on a climate system already significantly perturbed by the unintentional consequences of human activity. Many scientists are averse to opening that Pandora's box, preferring to mitigate climate through emissions reductions and worrying that those reductions might be undermined by a premature faith in a technical fix.

Nevertheless, some scientists argue that the world needs an emergency backup plan. They advocate doing careful and thorough research to examine the efficacy, costs, side effects, duration, and reversibility of any potential climate-change intervention.

One such advocate is National Academy of Sciences president Ralph Cicerone.² He favors separating research on geoengineering from actual implementation. Scientists should not proceed with an intervention, he asserts, until the proposed action is subjected to expert, international peer review, with opportunity for significant public involvement. He sees the need for a qualified agency to oversee the design, implementation, and monitoring of experiments, and he points to the actions of biologists in the 1970s who created ethical guidelines for genetic research.

David Keith of the University of Calgary points out that if serious scientists don't do the work, the field will be dominated by enthusiasts at the fringe, and that geoengineering schemes may be commercialized in a way that ends up being counterproductive.

Other scientists argue that doing any research on geoengineering schemes is dangerous. As Raymond Pierrehumbert of the University of Chicago puts it, "It is very unfortunate that the genie has been let out of the bottle just as the world has begun to awaken to the seriousness of climate change and the need to take real action." There's a real risk, he says, that unwarranted faith in the technology will "cut off at the knees actions that might start to make serious reductions in greenhouse emissions."

Even with the best science, no one can fully anticipate all the unintended consequences of a geoengineering measure. Can one conduct an experiment large enough to give a realistic assessment of a countermeasure without making the experiment so large that it becomes a significant intervention?

Another set of questions concerns geopolitics. If the international community did convene a body to govern the implementation of a certain geoengineering scheme, how would that body decide when to give the go-ahead? The decision would be complicated by the unequal global distribution of climate impacts, such as drought or increased monsoons, and by the unequal distribution of the possible consequences, good and bad. It's possible that a single nation, suffering worse effects than others, might attempt climate modification on its own.

Relative costs and risks

The proposed types of climate intervention vary widely, with the risks and benefits being quite specific to a particular action. During a public panel held in May at the University of California, Santa Barbara, Kurt House of Harvard University rated the commonly discussed actions by cost and risk, as sketched in the figure on page 26. Reducing CO₂ emissions has the lowest risk but the widest range of costs.

Albedo modifications

At the high end of the risk scale and low end of the cost scale fall techniques to reflect solar radiation with small particles in the stratosphere. Volcanic eruptions have given us some evidence for the impact of particles in the stratosphere. Eruptions large enough to loft soot into the stratosphere lowered global temperatures for a year or two afterward. Mount Pinatubo in 1991 hurled roughly 17 megatons of sulfur dioxide to heights of about 18 km. In the stratosphere, SO₂ gas forms highly reflective sulfate particles with residence times of a few years.

The cooling impact of volcanoes suggests that the artificial injection of aerosols might lower Earth's temperature. Paul Crutzen of the Max Planck Institute for Chemistry sparked the recent geoengineering debate in 2006 when he proposed³ the injection of about two megatons of SO₂ particles into the atmosphere annually to compensate for a doubling of CO₂. The paper attracted a lot of public attention because of its author: Crutzen won the 1995 Nobel Prize in Chemistry for his work on ozone chemistry in the stratosphere.

Alan Robock of Rutgers University is among those who have pointed to a number of problems with the sulfate idea.⁴ For one, increased albedo compensates only for higher temperatures; it does not mitigate the growing acidification of Earth's oceans or other consequences of greenhouse gases. For another, albedo enhancement is expected to reduce overall precipitation, especially in the tropics. Regional impacts such as reduced rainfall, soil moisture, and river flow were found in the wake of the Pinatubo eruption,⁵ and similar results have been seen in simulations of hypothetical geoengineering schemes.⁶

Mount Pinatubo also contributed to an increased rate of ozone depletion at the poles by providing particulate surfaces on which the ozone-depleting reactions with chlorofluorocarbons (CFCs) can occur. Simone Tilmes at the National Center for Atmospheric Research and colleagues recently simulated the effect of intentional injection of sulfates. They found that geoengineering would prolong—or possibly worsen—the ozone depletion for decades, even with the reductions in CFCs mandated by the 1987 Montreal Protocol.

The ozone hole was an unforeseen consequence of CFC emissions, notes Meinrat Andreae of the Max Planck Institute for Chemistry. He asks, "What makes us think we won't be in for another surprise if we inject so much sulfur into the atmosphere?"

Some view the stratospheric injection of sulfur as a stopgap measure, to shield Earth from higher temperatures while or until global greenhouse emissions can be reduced. If no such progress is made, the greenhouse gases will continue to build in the atmosphere, but the sun shield would mask the temperature rise. If the world for some reason stopped lofting sulfur into the stratosphere, Earth would be abruptly exposed to the far hotter temperatures expected in a world with far higher greenhouse gases.

Another way to reduce the solar heat flux reaching Earth's surface is to put deflectors in space. University of Arizona astronomer Roger Angel envisions a cloud of trillions of 0.6-meter-diameter, thin refractive screens to deflect sunlight.⁷ To offset a doubling of CO₂ over preindustrial levels would require a total mass of 20 million tons to block 1.8% of the solar radiation. Angel suggests a combination of electromagnetic acceleration and ion propulsion to loft a mass that large into space, at a projected cost of a few trillion dollars.

Removing CO₂

Other geoengineering ideas concern ways to accelerate removal of CO₂ from the atmosphere. The least contentious idea is to capture CO₂ as it is emitted from the stack of a coal-fired power plant and to sequester it in reservoirs. (For more on the storage of CO₂ see the article by Don DePaolo and Lynn Orr on page 46 of this issue.) A related idea is to pull the CO₂ out of the ambient air, but that research is still in its infancy. Growing trees and other biomass also takes CO₂ out of the atmosphere, and carbon credits are now given for reforestation projects.

A technique considered to pose higher risk than reforestation is ocean iron fertilization (OIF). The iron helps stimulate greater growth of phytoplankton in nutrient-rich regions of the ocean. The photosynthesis in these microorganisms takes CO₂ from the ocean's surface and releases oxygen. When the microorganisms die or are eaten, about 5–30% of their biomass sinks to the ocean's depths. Anthony Michaels of Proteus Environmental Technologies LLC in Los Angeles refers to OIF as "time shifting" since the carbon eventually gets reintroduced to the atmosphere after decades or centuries. Because of its relatively low price tag, OIF has become the focus of several companies interested in carbon removal technologies, presumably with the intent to sell carbon credits or offsets.

Phytoplankton bloom

In 12 field studies conducted since 1993, OIF was found to stimulate increased phytoplankton growth (see the figure at left), but those studies were not conducted at sufficiently large spatial scales or adequately long time scales to address OIF's efficacy in storing carbon. How much additional atmospheric CO₂ would be removed, and how long would it be sequestered? Might the blooms include harmful algae, or could biochemical processes produce methane or nitrous oxide—more potent greenhouse gases? Michaels is among a group of 16 scientists who have publicly asserted that it would be premature to sell carbon offsets for OIF unless the method is shown to remove CO₂, retain it for a quantifiable period of time, and have acceptable and predictable environmental impacts.⁸

Accelerated weathering

Raindrops contain some CO₂, so that the drops constitute a weak carbonic acid. Over geologically long time periods, weathering by rainfall dissolves rocks such as magnesium silicate, with magnesium and bicarbonate ions washing eventually into the oceans. The bicarbonate ions can combine with calcium to form calcium carbonate. When the calcium carbonate sinks to the deep ocean, it is sequestered for more than 1000 years, and the carbon is eventually recycled through Earth's mantle.

The oceans absorb about one-quarter of the CO₂ added annually to the atmosphere. The absorption is dependent, among other factors, on the alkalinity of the oceans' surface layer. As atmospheric CO₂ has increased, so has the acidity of Earth's oceans.

One of several ideas to accelerate the natural weathering cycle is to increase the oceans' alkalinity. For example, House and others have proposed a scheme to remove hydrochloric acid electrochemically from the oceans and to neutralize it by reacting it with silicate rocks.⁹ To offset the output of 1 gigaton of carbon per year—one-seventh of today's annual global emissions—House estimates that his weathering scheme would require a seawater flow rate equal to that of 100 large sewage treatment plants and the consumption of about 10 gigatons of basalt rock.

The enormous scale of such geoengineering schemes helps to underscore the importance of getting things right.

Barbara Goss Levi

References

1. 1. For a review, see D. Keith, Annu. Rev. Energy Environ. 25, 245 (2000).
2. 2. R. Cicerone, Climatic Change, 77, 221 (2006).
3. 3. P. Crutzen, Climatic Change 77, 211 (2006).
4. 4. A. Robock, Bull. Atomic Sci. 64, 14 (2008).
5. 5. K. E. Trenberth, A. Dai, Geophys. Res. Lett. 34, L15702 (2007).
6. 6. S. Tilmes, R. Muller, R. Salawitch, SciencExpress 24 April 2008.
7. 7. R. Angel, Proceed. Nat. Acad. Sci. 103, 17184 (2006).
8. 8. K. O. Buesseler et al., Science 319, 162 (2008).
9. 9. H. S. Kheshgi, Energy 20, 915 (1995), K. Z. House, C. H. House, D. P. Schrag, M. J. Aziz, Environ. Sci. Technol. 41, 8464 (2007).

Geoengineering: What, how, and for whom?

February 2009, page 10

I have been thinking about geoengineering for climate modification since I worked on the committee that produced the 1992 National Academies report, Policy Implications of Greenhouse Warming. Over the years, and increasingly now, I have been puzzled by the scientific community’s attitudes toward the issue; those puzzles were raised again by Barbara Goss Levi’s story (PHYSICS TODAY, August 2008, page 26).

It has been customary to discuss geoengineering without offering an explicit definition. I propose the following one: Geoengineering is purposeful action intended to manipulate the environment on a very large—especially global—scale. Geoengineering is, presumably, undertaken to reverse or reduce impacts of human actions.

Decreasing human emissions of carbon dioxide and other greenhouse gases is a good idea for many reasons, including climate modification; yet it is not clear to me why manipulating the CO₂ content of the atmosphere is not considered geoengineering. If, using the above definition but narrowing it to the case under consideration, geoengineering includes purposeful manipulation of physical, chemical, and biological variables on the global scale for the purpose of changing global climate, then manipulation of carbon dioxide concentrations fits the definition as well as do, for example, manipulating atmospheric aerosol content to control albedo or manipulating the ocean’s iron content to increase the long-term oceanic storage of carbon.

Exclusion of carbon dioxide manipulation from geoengineering has led to a double standard in considering possible negative consequences. There is legitimate concern about side effects of particulate manipulation and the like, but I have not heard much worrying about manipulating carbon dioxide.

In a highly nonlinear feedback-controlled system like global climate, we would expect complex hysteresis effects: Decreasing a control variable such as greenhouse gas will not necessarily lead the climate back along some path like the one it followed when the control variable was increased. The end state of control-variable manipulation may not at all resemble the original state before the control variable was increased, nor will it necessarily be a state we want to be in. I have heard of no concern about those possibilities, which might be rate dependent, involve transient behavior not to our liking, or lead us through bifurcations into unexpected states.

It seems to me we need to be concerned about possible not-so-benign effects of decreasing carbon dioxide and other greenhouse gases before we grab the control knob and turn it down. I hope someone is at least exercising suitable climate models, if relevant ones exist, to examine possible end states, paths to them, and transient effects of carbon dioxide geoengineering.

Robert A. Frosch

(robert_frosch@harvard.edu)

Harvard Kennedy School

Cambridge, Massachusetts

The Issues and Events report on the viability of geoengineering to counter global warming did not address the ethical issue. I use the following fable to illustrate the point.

Once upon a time in an idyllic country, near a small town and a farming community, a rope hung out of the sky. One pull on the rope changed the weather from fine and sunny to cloudy and rainy, and the next pull changed it back. For many years the people cooperated; the farmers used the rains to help grow crops, and the townspeople enjoyed the sunny periods. But there came a time when the townspeople protested the rain and wanted more sunshine. The farmers were concerned about their crops. And so arguments broke out, with a person from the town pulling on the rope, followed quickly by a farmer pulling it again, and they pulled and pulled and . . . broke the rope.

Given that the climate is changing because of inadvertent consequences of human activities, the question arises as to whether efforts should be made to deliberately change climate to counteract the warming. Aside from the wisdom and ability to do such a thing economically, the more basic question is the ethical one of who controls the rope. Who makes the decision on behalf of all humanity and other residents of planet Earth to change the climate deliberately?

Climate change is not necessarily bad. The climate has always varied to some degree, and changes have occurred over decades and millennia. Humans and other creatures have adapted to the changes or perished; it is a part of evolution. Changes projected with increased greenhouse gases in the atmosphere may have some aspects that could be regarded as bad; increased heat waves and wildfires in summer, increased and more intense droughts, heavier rains and risk of flooding, stronger storms, decreases in air quality, and increases in bugs and disease are all likely threats. But in some areas, climates improve, high-latitude continents become more equable, growing seasons are longer, and so on. There are winners and losers. And it is possible to adapt to such changes—at least if the changes occur slowly enough. In other words, key issues are the rate and duration of change, perhaps more so than the nature of the new climate. In that sense, it is the disruptive part of climate change that might be argued as being bad.

Given that climate change is not universally condemned, how can anyone justify deliberately acting to change the climate to benefit any particular group, perhaps even a majority? The ethical questions associated with climate manipulation loom so large that some forms of geoengineering are simply unacceptable. The forms that are acceptable include those that reduce emissions and mitigate the rates of change or reduce the amount of carbon dioxide in the atmosphere. Forms that propose to block sunlight in some fashion, perhaps to emulate a volcanic eruption, would change the hydrological cycle and weather patterns in ways that would be simply unacceptable, even if they were doable. The cost and viability of any such proposals are other major issues, but in my view, they are overwhelmed by the ethical considerations.

Kevin E. Trenberth

(trenbert@ucar.edu)

National Center for Atmospheric Research

Boulder, Colorado

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