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What Will It Take to Solve Climate Change?

This article was published in Scientific American’s former blog network and reflects the views of the author, not necessarily those of Scientific American


Australia had to add a new color to its weather maps this week. Meteorologists used royal purple to denote an off-the-charts high temperature of 50 degrees Celsius (122 degrees Fahrenheit), part of an unprecedented heat wave and ongoing wildfires occurring down under this month. On the other side of the globe, 2012 proved the hottest year on record in the contiguous U.S., surpassing the previous record-holder by a full degree F (0.6 deg C). In short, global warming is continuing to turn up the heat—so what are we going to do about it?

The goal is simple: reduce greenhouse gas emissions to restrain future warming or even begin to draw down carbon dioxide concentrations in the atmosphere. But the challenge of achieving that goal is large—greenhouse gas emissions are intimately related to fossil fuel combustion, which is the motor of the global economy.

One idea to begin to solve this problem, mooted in 2004 by Princeton University mechanical engineer Robert Socolow and ecologist Stephen Pacala, was to identify what the scientists dubbed "wedges"—one billion metric ton reductions in carbon emissions that could be maintained for the next 50 years. So, for example, stopping any further increase in greenhouse gas emissions could be done by employing several of these wedges, such as doubling vehicle fuel efficiency or replacing coal-fired power plants with nuclear ones.


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Employ enough of these wedges—seven in the estimation of Socolow and Pacalaand the problem of climate change begins to dissipate. And the researchers offered 15 potential wedges—ranging from carbon capture and storage to ending deforestation—to achieve the goal. As the co-authors put it in the paper presenting the idea published in Science: "Humanity already possesses the fundamental scientific, technical, and industrial know-how to solve the carbon and climate problem."

Great! The only problem is: if we do indeed possess the know-how, we have yet to employ it. Eight years later, global greenhouse gas emissions continue to grow faster than ever. We have lost time, and that time will cost us, both in terms of the cost of combating climate change and the ultimate impacts.

According to a new analysis published online in Environmental Research Letters on January 9, the world now likely needs 12 wedges just to get back to the business-as-usual scenario outlined by Socolow and Pacala in 2004. Add another nine billion ton wedges if you want to stabilize emissions at last year's levels, and add another 10 if you'd like to keep greenhouse gas concentrations from rising above 500 parts-per-million. Already, concentrations are at 394 ppm, up from 280 ppm before the dawn of widespread fossil fuel burning. That's if you also want the global economy to continue to grow at the same time.

Such global growth may be vital as societies strive to bring modern energy to the 2 billion or so people still reliant on wood, dung and kerosene for their cooking and lighting needs. Even more challenging, the key to reducing emissions is reducing the burning of fossil fuels, or at least the impacts of that burning—and all the technologies needed to do that are stalled (CCS), slow-moving (nuclear) or immature (renewables). The world will need to deploy "tens of terawatts of carbon-free energy in the next few decades," as the researchers write in Environmental Research Letters.

What such a "transformation" would mean specifically remains entirely undiscussed in the analysis, as Socolow notes in a written critique of the paper shared this week with journalists. Regardless, that kind of energy revolution certainly seems challenging, which is why some have begun to wonder whether it's time to at least explore technologies that might reduce the worst of global warming, collectively known as geoengineering, such as fertilizing the ocean with iron or artificial volcanoes. Of course, such solutions present their own challenges like: who controls the planetary thermostat? "The stricter the [climate] goal, the greater the risk of recklessness," such as ill-considered geoengineering schemes, warns Socolow.

Or, as earth system scientist Steven Davis of the University of California, Irvine, and lead author of the wedges reanalysis argues: "The only real solution to climate change is to stop dumping CO2 into the atmosphere altogether." If we want to begin to restrain global warming, we better get started—and soon.