Can Tech Avert Climate Change?
Groundbreaking New Report on Geoengineering Tackles Carbon Dioxide Removal Experiments
Reflecting Sunlight to Cool Earth: The NAS Weighs Controversial Measures in New Report
Groundbreaking New Report on Geoengineering Tackles Carbon Dioxide Removal Experiments
Brenda Ekwurzel
Union of Concerned Scientists
February 10, 2015
http://blog.ucsusa.org/groundbreaking-new-report-on-geoengineering-tackles-carbon-dioxide-removal-experiments-624
The scientific body established by a law signed by President Lincoln released two groundbreaking reports today on geoengineering. The National Research Council of the U.S. National Academy of Sciences (NAS) emphasized in each report that reducing heat-trapping emissions and adapting to a changing climate are the two main options for reducing the risks of climate change.
The NAS committee, chaired by Marcia McNutt, recommended avoiding the terms “geoengineering” or “climate engineering,” which imply an engineering precision that is not warranted. Plus “geological engineering” has a different meaning in the context of mining. The committee preferred to define the term “climate intervention” as “purposeful actions intended to produce a targeted change in some aspect of the climate.”
The first report assesses ways to strike at the core of the problem by intentional carbon dioxide removal and reliable sequestration. These have the potential to reduce the risks of most consequences that stem from overloading the atmosphere with carbon dioxide, including ocean acidification. The second report, assesses ways of reflecting sunlight to cool Earth. (To learn more about this report check out the blog by my colleague Peter Frumhoff.)
Climate intervention raises questions of governance
Both reports also point out that intentional experiments such as these raise profound issues regarding governance that are at present not well developed in most countries or international organizations.
Appropriately, given the role of the NAS to advise the federal government on matters of science or of a technical nature, the reports recognize that other disciplines need to weigh in on improving governance before deployment should be considered in many cases. For example, the Bipartisan Policy Center and the Oxford Principles in the UK represent early explorations of governance.
One of the issues raised is that those who may experience the consequences of intentional experiments would ideally be brought into the review of proposals, and prior approval would be sought before conducting experiments in the field. Another idea is to have an independent team of experts study potential consequences of any experiment proposed.
Carbon removal and sequestration more costly than reducing emissions
Among the key findings from the report on carbon dioxide removal and reliable sequestration is that the costs of many current proposals are likely to exceed that of reducing heat-trapping emissions through wide deployment of renewable energy sources and significant reductions in fossil fuel combustion.
For example, current cost estimates for scrubbing the parts per million carbon dioxide concentrations from the atmosphere are exceedingly high. Though less costly then direct air capture, costs are still high for capturing carbon dioxide directly at a concentrated point source such as a bioenergy source. As far as the reliable sequestration portion of the entire enterprise, saline aquifers seem the most promising of the geologic reservoirs examined in the United States.
The report noted that some carbon dioxide removal and reliable sequestration projects have already been explored with unequal results. For example, reforestation can sequester carbon for at least the lifetime of the trees. Far riskier is intentional acceleration of carbon dioxide removal by enhancing the biological uptake in the ocean through iron fertilization. According to the report, “deploying ocean iron fertilization at climatically relevant levels poses risks that outweigh potential benefits.”
Decades to achieve – not a quick fix
Most proposals would likely take a decade or longer to achieve modest climate effects. What if the funding stopped for a carbon dioxide removal experiment? The report assesses this as well. The committee determined that any sudden stoppage of a carbon dioxide removal and sequestration experiment is considered a low-risk action. Given the time delay of most proposals, this gives time to conduct thorough research into potential consequences (e.g. earthquakes associated with injecting carbon deep into geologic reservoirs). Most of the carbon removal and sequestration research experiments examined were considered in the report to be relatively regional with regard to governance aspects.
The bottom line is that this report is a call for further research into safe ways for carbon dioxide removal and reliable sequestration. In particular, ramping up research into land use and reforestation approaches seem the least risky of those covered in the report. The National Science Foundation and U.S. federal agencies could spur innovation with investments in transparent research programs on carbon dioxide removal and reliable sequestration.
Brenda Ekwurzel is a senior climate scientist and assistant director of climate research and analysis at UCS. She has expertise on many aspects of climate variability including Arctic Ocean and sea ice, wildfires, groundwater, and coastal erosion. She holds a Ph.D. in isotope geochemistry from Columbia University (Lamont-Doherty Earth Observatory).
Reflecting Sunlight to Cool Earth: The NAS Weighs Controversial Measures in New Report
Peter Frumhoff
Union of Concerned Scientists
February 10, 2015
http://blog.ucsusa.org/reflecting-sunlight-to-cool-earth-new-nas-report-weighs-controversial-measures-623
The president’s science advisor John P. Holdren has often observed that humanity has three basic options for dealing with climate change: Mitigation (reducing heat-trapping emissions), adaptation (coping with unavoidable impacts of climate change), and suffering. The more swiftly we both mitigate and adapt, the less suffering we endure and impose on future generations.
Suppose, however, that we falter and temperatures continue to rise to dangerous levels. In a climate emergency, facing high risks of major and otherwise unavoidable impacts, should the U.S. or other governments consider forced cooling of Earth by injecting reflecting aerosol particles into the stratosphere?
Today, the U.S. National Academy of Sciences (NAS) weighs in with a pair of major reports examining the scientific basis for considering this and other possible “climate interventions” — deliberate, potentially large-scale actions to reflect sunlight away from Earth or remove carbon dioxide from the atmosphere should mitigation and adaptation prove insufficient to limit the risks of dangerous climate warming.
Kudos to the National Research Council (NRC) panel, chaired by Marcia McNutt, editor-in-chief of the journal Science and former director of the U.S. Geological Survey, for tackling this set of challenging and controversial issues. It is one of a growing number of scientific and related policy assessments on a suite of potential and problematic climate responses most commonly referred to as “geoengineering.”
Reflecting sunlight to cool Earth
Here’s a synopsis of key findings from the NRC report on Climate Intervention: Reflecting Sunlight to Cool Earth. (In a related post, my colleague Brenda Ekwurzel looks at their report on Climate Intervention: Carbon Dioxide Removal and Reliable Sequestration):
“Technologies that prevent sunlight from reaching Earth’s surface could reduce average global temperatures within a few years, similar to the effects of large volcanic eruptions. While many albedo-modification [i.e. solar energy reflecting] techniques have been proposed… two strategies that could potentially have a significant impact are injection of aerosols into the stratosphere and marine cloud brightening. [T]hese methods would not require major technological innovation to be implemented and are relatively inexpensive…
However, albedo modification would only temporarily mask the warming effect of greenhouse gases and would not address atmospheric concentrations of CO2 or related impacts such as ocean acidification. In the absence of CO2 reductions, albedo-modification activities would need to be sustained indefinitely and at increasingly large scales to offset warming, with severe negative consequences if they were to be terminated. In addition, albedo modification introduces secondary effects on the ozone layer, precipitation patterns, terrestrial and marine ecosystems, and human health, with unknown social, political, and economic outcomes.
Many of the processes most relevant to albedo modification — such as those that control the formation of clouds and aerosols — are among the most difficult components of the climate system to model and monitor. Present-day observational capabilities lack sufficient capacity to monitor the environmental effects of an albedo-modification deployment. Improvements in the capacity to monitor direct and indirect changes on weather, climate, or larger Earth systems and to detect unilateral or uncoordinated deployment could help further understanding of albedo modification and climate science generally.
[I]t would be “irrational and irresponsible” to implement sustained albedo modification without also pursuing emissions mitigation, carbon dioxide removal, or both. [The Committee] oppose[s] deployment of albedo-modification techniques, but recommend[s] further research, particularly “multiple-benefit” research that simultaneously advances basic understanding of the climate system and quantifies the technologies’ potential costs, intended and unintended consequences, and risks.
Albedo-modification research will have legal, ethical, social, political, and economic ramifications. The committee recommend[s] the initiation of a serious deliberative process to examine what international research governance structures may be needed beyond those that already exist, and what types of research would require such governance. The degree and nature of governance should vary by activity and the associated risks, and should involve civil society in decision-making through a transparent and open process.”
No substitute for dramatic reductions in heat-trapping emissions
In other words: Proposed strategies to alter the amount of sunlight hitting the Earth’s surface by (for example) deliberately injecting millions of tons of sulfate aerosols into the stratosphere pose enormous risks and uncertainties and don ‘t address the underlying causes of global warming or other major risks from rising concentrations of carbon dioxide, such as ocean acidification. They should not be deployed today and we should do everything possible to avoid their being deployed in the future. As the NRC report emphasizes, there is no substitute for dramatic reductions in heat-trapping emissions. Preventative medicine is far more attractive than getting treated in the emergency room.
But the Committee also recommends the U.S. government invest in an “albedo-modification research program” focused on improving understanding of the intended and unintended impacts of these technologies on climate, people, and ecosystems. They consider — and firmly reject — the “moral hazard” argument that such research would somehow distract from efforts to reduce emissions, concluding that “as a society we have reached a point where the severity of the potential risks from climate change…outweigh[s] the potential [moral hazard] risks associated with a suitably designed and governed research program.”
I strongly agree. We need to better understand these technologies and their risks, even if we are determined to never deploy them. They are relatively low-cost, and if deployed unilaterally by others, would have global consequences. In the U.S. and internationally, societal debate over their use would be well served by better understanding their risks and consequences. A fuller understanding of their risks, informed by science, might well reinforce our collective determination to never use them and motivate greater commitment to mitigation and adaptation. And, should we falter in that effort, we would be well-served to better understand the impacts of such emergency-room measures.
Needed: a transparent, participatory process to guide research on impacts and risks
That said, the question of who decides what research is appropriate is tricky. To date, studies have largely been confined to computer modeling. The NRC notes that “small-scale field experiments with controlled emissions [e.g. releasing reflecting aerosols into the atmosphere] may….be helpful.” Some scientists are eager to initiate field research. In my view, the NRC Committee has it exactly right when they call for any planning of such research to be subject to a “serious deliberative process” to weigh options for its governance. Such a process, they argue, should be fully transparent and informed by the active participation of civil society.
That process should begin now and subsequent guidance on the governance of albedo-modification research established before the U.S. supports any scale-up of albedo-modification research.
Peter Frumhoff is a global change ecologist and serves as chief scientist for the UCS climate campaign. Dr. Frumhoff is an internationally-recognized expert on climate change impacts, climate science and policy, tropical forest conservation and management, and biological diversity. He holds a Ph.D. in Ecology