by Naomi Klein
IV. Aided by investments like these, the ethanol boom was responsible for 20–40 percent of the spike in agricultural commodity prices in 2007–2009, according to a survey by the National Academy of Sciences.
V. Puerile humor of this sort is a recurring theme in Branson’s PR machine (the company once painted “Mine’s Bigger than Yours” on the side of a new Airbus A340-600; boasted of its business-class seats that “size does matter”; and even flew a blimp over London emblazoned with the slogan “BA [British Airways] Can’t Get It Up!!”).
VI. To quote one scathing assessment of the project by sociologist Salvatore Babones, “If two words can capture the extraordinary redistribution of wealth from workers to the wealthy over the past forty years, the flagrant shamelessness of contemporary conspicuous consumption, the privatization of what used to be public privileges and the wanton destruction of our atmosphere that is rapidly leading toward the extinction of nearly all non-human life on earth, all covered in a hypocritical pretense of pious environmental virtue . . . those two words are Virgin Galactic.”
VII. Including sustainability consultant Brendan May, founder of the Robertsbridge Group. “Of course you can segregate fuel according to its source,” May writes. “If there’s a will, there’s a way. . . . At present, there’s just no will.”
VIII. In 2012, he went so far as to offer to invest roughly $8 billion in an expansion of Virgin Atlantic’s operations at Heathrow if the government would approve the new runway—a prospect that once again raises questions about Branson’s claims to be too broke to keep up with his $3 billion climate pledge.
IX. Branson is apparently no great fan of paying taxes generally, as his byzantine network of offshore holding companies in the Channel Islands and British Virgin Islands attests. Indeed he spent a night in jail and received a hefty fine after getting caught in an illegal cross-border tax avoidance scam when running his first company in 1971. “I was a criminal,” Branson writes of his jailhouse revelation in his autobiography.
8
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DIMMING THE SUN
The Solution to Pollution Is . . . Pollution?
“Geoengineering holds forth the promise of addressing global warming concerns for just a few billion dollars a year.”
—Newt Gingrich, former speaker of the U.S. House of Representatives, 20081
“Our science is a drop, our ignorance a sea.”
—William James, 18952
It’s March 2011 and I have just arrived at a three-day retreat about geoengineering in the Buckinghamshire countryside, about an hour and a half northwest of London. The meeting has been convened by the Royal Society, Britain’s legendary academy of science, which has counted among its fellows Isaac Newton, Charles Darwin, and Stephen Hawking.
In recent years, the society has become the most prominent scientific organization to argue that, given the lack of progress on emission reduction, the time has come for governments to prepare a technological Plan B. In a report published in 2009, it called upon the British government to devote significant resources to researching which geoengineering methods might prove most effective. Two years later it declared that planetary-scale engineering interventions that would block a portion of the sun’s rays “may be the only option for reducing global temperatures quickly in the event of a climate emergency.”3
The retreat in Buckinghamshire has a relatively narrow focus: How should research into geoengineering, as well as eventual deployment, be governed? What rules should researchers follow? What bodies, if any, will regulate these experiments? National governments? The United Nations? What constitutes “good governance” of geoengineering? To answer these questions and others, the society has teamed up with two cosponsors for the retreat: the World Academy of Sciences based in Italy, which focuses on promoting scientific opportunities in the developing world, and the Environmental Defense Fund, which has described geoengineering as a “bridging tool” (much as it has described natural gas).4 That makes this conference both the most international gathering about geoengineering to date, and the first time a major green group has publicly offered its blessing to the exploration of radical interventions into the earth’s climate system as a response to global warming.
The venue for this futuristic discussion is an immaculately restored sixty-two-room redbrick Georgian mansion called Chicheley Hall, once a set in a BBC production of Pride and Prejudice, and the Royal Society’s newly acquired retreat center. The effect is wildly anachronistic: the estate’s sprawling bright green lawns, framed by elaborately sculpted hedges, seem to cry out for women in corseted silk gowns and parasols discussing their suitors—not disheveled scientists discussing a parasol for the planet. And yet geoengineering has always had a distinctly retro quality, not quite steampunk, but it definitely harkens back to more confident times, when taking control over the weather seemed like the next exciting frontier of scientific innovation—not a last-ditch attempt to save ourselves from incineration.
After dinner, consumed under towering oil paintings of plump-faced men in silver wigs, the delegates are invited to the wood-paneled library. There, about thirty scientists, lawyers, environmentalists, and policy wonks gather for the opening “technical briefing” on the different geoengineering schemes under consideration. A Royal Society scientist takes us through a slide show that includes “fertilizing” oceans with iron to pull carbon out of the atmosphere; covering deserts with vast white sheets in order to reflect sunlight back to space; and building fleets of machines like the ones competing for Richard Branson’s Earth Challenge that would suck carbon out of the air.
The scientist explains that there are too many such schemes to evaluate in depth, and each presents its own particular governing challenge. So for the next three days, we will zero in on the geoengineering methods the scientists here consider most plausible and promising. These involve various means of injecting particles into the atmosphere in order to reflect more sunlight back to space, thereby reducing the amount of heat that reaches the earth. In geoengineering lingo, this is known as Solar Radiation Management (SRM)—since these methods would be attempting to literally “manage” the amount of sunlight that reaches earth.
There are various possible sun-dimming approaches. The most gleefully sci-fi is space mirrors, which is quickly dismissed out of hand. Another is “cloud brightening”: spraying seawater into the sky (whether from fleets of boats or from towers on shore) to create more cloud cover or to make clouds more reflective and longer lasting. The most frequently discussed option involves spraying sulfate aerosols into the stratosphere, whether via specially retrofitted airplanes or a very long hose suspended by helium balloons (some have even suggested using cannons).
The choice to focus exclusively on SRM is somewhat arbitrary given that ocean fertilization experiments have been conducted on several occasions, including a heavily reported “rogue” test off the coast of British Columbia in 2012. But SRM is attracting the lion’s share of serious scientific interest: sun blocking has been the subject of over one hundred peer-reviewed papers, and several high-level research teams are poised to run open-air field trials, which would test the mechanics of these schemes using ships, planes, and very long hoses. If rules and guidelines aren’t developed soon (including, as some are suggesting, banning field tests outright), we could end up with a research Wild West.5
Spraying sulfate into the stratosphere is often referred to as “the Pinatubo Option,” after the 1991 eruption of Mount Pinatubo in the Philippines. Most volcanic eruptions send ash and gases into the lower atmosphere, where sulfuric acid droplets are formed that simply fall down to earth. (That was the case, for instance, with the 2010 Icelandic volcano that grounded many European flights.) But certain, much rarer eruptions—Mount Pinatubo among them—send high volumes of sulfur dioxide all the way up to the stratosphere.
When that happens, the sulfuric acid droplets don’t fall back down: they remain in the stratosphere, and within weeks can circula
te to surround the entire planet. The droplets act like tiny, light-scattering mirrors, preventing the full heat of the sun from reaching the planet’s surface. When these larger volcanic eruptions occur in the tropics, the aerosols stay suspended in the stratosphere for roughly one to two years, and the global cooling effects can last even longer.
That’s what happened after Pinatubo. The year after the eruption, global temperatures dropped by half a degree Celsius, and as Oliver Morton noted in Nature, “Had there not been a simultaneous El Niño, 1992 would have been 0.7 degrees cooler, worldwide, than 1991.”6 That figure is notable because we have warmed the earth by roughly the same amount thus far with our greenhouse gas emissions. Which is why some scientists have become convinced that if they could just find a way to do artificially what those large eruptions do naturally, then they could force down the temperature of the earth to counteract global warming.
The scientist leading the briefing starts with the pros of this approach. He observes that the technology to pull this off already exists, though it needs to be tested; it’s relatively cheap; and, if it worked, the cooling effects would kick in pretty quickly. The cons are that, depending on which sun-blocking method is used and how intensively, a permanent haze could appear over the earth, potentially making clear blue skies a thing of the past.7 The haze could prevent astronomers from seeing the stars and planets clearly and weaker sunlight could reduce the capacity of solar power generators to produce energy (irony alert).
But the biggest problem with the Pinatubo Option is that it does nothing to change the underlying cause of climate change, the buildup of heat-trapping gases, and instead treats only the most obvious symptom—warmer temperatures. That might help control something like glacial melt, but would do nothing about the increased atmospheric carbon that the ocean continues to soak up, causing rapid acidification that is already taking a heavy toll on hard-shelled marine life from coral to oysters, and may have cascading impacts through the entire aquatic food chain. On the other hand, we hear, there could be some advantages to allowing atmospheric carbon dioxide levels to increase while keeping temperatures artificially cool, since plants like carbon dioxide (so long as it’s not accompanied by scorching heat and drought) and they might well do better in what would essentially become an artificial global greenhouse.
Oh, and another con: once you start spraying material into the stratosphere to block the sun, it would basically be impossible to stop because if you did, all the warming that you had artificially suppressed by putting up that virtual sunshade would hit the planet’s surface in one single tidal wave of heat, with no time for gradual adaptation. Think of the wicked witches of fairy tales, staying young by drinking ill-gotten magical elixirs, only to decay and wither all at once when the supply is abruptly cut off.
One solution to this “termination problem,” as our British guide politely describes it, would be to suck a whole lot of carbon out of the atmosphere while the shade was still up so that when the particles dissipate and the sun beams down full bore, there is less heat-trapping gas in the atmosphere to augment the warming. Which would be fine except for the fact that we don’t actually know how to do that on anything close to the required scale (as Richard Branson has discovered).
Listening to all this, a grim picture emerges. Nothing on earth would be outside the reach of humanity’s fallible machines, or even fully outside at all. We would have a roof, not a sky—a milky, geoengineered ceiling gazing down on a dying, acidified sea.
And it gets worse, because our guide has saved the biggest con for last. A slide comes up showing a map of the world, with regions color-coded based on projections showing how severely their rainfall will be affected by injecting sulfur dioxide into the stratosphere. Precipitation in Europe and North America appears minimally changed, but Africa’s equatorial region is lit up red, an indication of serious drought. And though the borders are hazy, parts of Asia appear to be in trouble as well because the drop in land temperature caused by a weaker sun could also weaken the summer monsoons, the main source of rainfall in these regions.
Up to this point, the audience has been quietly listening, but this news seems to wake up the room. One participant interrupts the presentation: “Let’s put aside the science and talk about the ethics,” he says, clearly upset. “I come from Africa and I don’t like what I’m seeing with precipitation.”I Indeed, one of the society’s own reports on geoengineering acknowledges that Solar Radiation Management “could conceivably lead to climate changes that are worse than the ‘no SRM’ option.”8
The African delegate shakes his head. “I don’t know how many of us will sleep well tonight.”
Warming Up to “Horrifying”
Schemes for deliberately intervening in the climate system to counteract the effects of global warming have been around for half a century at least. In fact, when the President’s Science Advisory Committee issued a report warning Lyndon B. Johnson about climate change in 1965, the authors made no mention of cutting emissions. The only potential solutions considered were technological schemes like modifying clouds and littering oceans with reflective particles.9
And well before it was seen as a potential weapon against global warming, weather modification was simply seen as a weapon. During the Cold War, U.S. physicists imagined weakening the nation’s enemies by stealthily manipulating rainfall patterns, whether by causing droughts or by generating targeted storms that would turn a critical supply route into a flooded mess, as was attempted during the Vietnam War.10
So it’s little wonder that mainstream climate scientists have, until quite recently, shied away from even discussing geoengineering. In addition to the Dr. Strangelove baggage, there was a widespread fear of creating a climate moral hazard. Just as bankers take greater risks when they know governments will bail them out, the fear was that the mere suggestion of an emergency techno-fix—however dubious and distant—would feed the dangerous but prevalent belief that we can keep ramping up our emissions for another couple of decades.
More out of despair than conviction, the geoengineering taboo has been gradually eroding over the past decade. A significant turning point came in 2006 when Paul Crutzen, who won the Nobel Prize in chemistry for his breakthrough research on the deterioration of the ozone layer, wrote an essay arguing that the time had come to consider injecting sulfur into the stratosphere as an emergency escape route from severe global warming. “If sizeable reductions in greenhouse gas emissions will not happen and temperatures rise rapidly, then climatic engineering . . . is the only option available to rapidly reduce temperature rises and counteract other climatic effects,” he wrote.11
Crutzen created some space for preliminary research to take place, but geoengineering’s real breakthrough came after the Copenhagen summit flopped in 2009, the same year that climate legislation tanked in the U.S. Senate. Soaring levels of hope had been pinned on both processes and when neither panned out, would-be planet hackers came out of their labs, positioning even the most seemingly outlandish ideas as the only realistic options left—especially with a world economic crisis making costly energy transformations seem politically untenable.
The Pinatubo Option has become a media favorite thanks in large part to the work of Nathan Myhrvold, the excitable former Microsoft chief technology officer who now runs Intellectual Ventures, a company that specializes in eclectic high-tech inventions and is often described as a vehicle for patent trolling.12 Myhrvold is a made-for-TV character—a child prodigy turned physicist turned tech star, as well as an avid dinosaur hunter and wildlife photographer. Not to mention a formally trained amateur cook who spent millions researching and co-writing a six-volume bible on molecular gastronomy.
In 2009, Myhrvold and his team unveiled details for a contraption they called the “StratoShield,” which would use helium balloons to suspend a sulfur dioxide–spraying tube thirty kilometers into the sky. And he wasted no time pitching it as a substitute for government action: just two days after the Copenha
gen summit concluded, Myhrvold was on CNN boasting that his device—which he said could deliver a “Mount Pinatubo on demand”—had the power to “negate global warming as we have it today.”13
Two months earlier, Steven D. Levitt and Stephen J. Dubner’s global bestseller SuperFreakonomics had come out, devoting an entire awestruck chapter to Myhrvold’s hose to the sky. And whereas most scientists engaged in this research are careful to present sun blocking as a worst-case scenario—a Plan B to be employed only if Plan A (emission cuts) proves insufficient—Levitt and Dubner declared that the Pinatubo Option was straight-up preferable to getting off fossil fuels. “For anyone who loves cheap and simple solutions, things don’t get much better.”14
Most of those calling for more geoengineering research do so with significantly less glee. In September 2010, the New America Foundation and Slate magazine held a one-day forum in Washington, D.C., titled “Geoengineering: The Horrifying Idea Whose Time Has Come?”15 That one sentence pretty much sums up the tone of grim resignation that has characterized the steady stream of conferences and government reports that have inched geoengineering into the political mainstream.
This gathering at Chicheley Hall is another milestone in this gradual process of normalization. Rather than debate whether or not to engage in geoengineering research—as most previous gatherings have done—this conference seems to take some kind of geoengineering activity as a given (or else why would it need to be “governed”). Adding to the sense not just of inevitability but general banality, the organizers have even given this process a clunky acronym: SRMGI, the Solar Radiation Management Governance Initiative.
Geoengineering debate generally takes place within a remarkably small and incestuous world, with the same group of scientists, inventors, and funders promoting each other’s work and making the rounds to virtually every relevant discussion of the topic. (Science journalist Eli Kintisch, who wrote one of the first books on geoengineering, calls them the “Geoclique.”) And many of the members of that clique are in attendance here. There is David Keith, the wiry, frenetic physicist, then at the University of Calgary (now at Harvard), whose academic work has a major focus on SRM, and whose carbon-sucking machine—blessed by both Richard Branson and Bill Gates—stands to make him rather rich should the idea of a techno fix for global warming take off. This kind of vested interest is a recurring theme: many of the most aggressive advocates of geoengineering research are associated with planet-hacking start-ups, or hold patents on various methods. This, says Colby College science historian James Fleming, gives them “skin in the game” since these scientists stand “to make an incredible amount of money if their technique goes forward.”16