Authors: Ronald Bailey
Weitzman's analysis also assumes that humanity will not have the time to learn about any impending catastrophic impacts from global warming. But midcourse corrections are possible with climate change. People would notice if the average temperature began to increase rapidly, for example, and would act to counteract it by cutting emissions, deploying low-carbon technologies, or even engaging in geoengineering. Other low-probability calamities, such as the entire Earth being transformed into strange matter by strangelets produced in high energy physics experiments, don't allow for learning. As Nordhaus dryly notes, “There is no point in revising our views about strangelets in the microsecond after we discover that the calculations of the physicists are wrong.” And yet we do not shut down such experiments.
At the end of his critique of Weitzman's Dismal Theorem, Nordhaus investigates what combination of factors would actually produce a real climate catastrophe. He defines a catastrophic outcome as one in which world per capita consumption declines by at least 50 percent below current levels. Since output is projected to grow substantially over the coming century, this implies a decline that is at least 90 percent below the projected baseline. In contrast, the most extreme climate scenario presented by the gloomy
Stern Review
had people living in 2200 making do with only nine times current per capital consumption instead of thirteen times current consumption.
Nordhaus ran a number of scenarios through the Dynamic Integrated Climate-Economy (DICE) model, his integrated assessment model. DICE would produce a catastrophic result only if temperature sensitivity was at 10°C, economic damage occurred rapidly at a tipping point of 3°C, and nobody took any action to prevent the catastrophic chain of events. Interestingly, even when setting all of the physical and damage parameters to extreme values, humanity still had eighty years to cut emissions by 100 percent in order to avoid disaster.
Finally, the question must be asked: Why has no one ever applied a Dismal Theorem analysis to evaluate the nonzero probability that bad government policy will cause a civilization-wrecking catastrophe?
Parsing the Poisonous Politics of Climate Change
The public debate in the United States over climate change science and policy is particularly poisonous. On the one hand, Oklahoma senator James Inhofe denounces climate change science, declaring that “man-made global warming is the greatest hoax ever perpetrated on the American people.” On the other, former vice president Al Gore likens those who doubt the seriousness of climate change to odious Holocaust “deniers.” What prompts such a level of discord and disrespect? Yale law professor Dan Kahan explains that climate change is not chiefly a fight over science, but is instead one involving a clash of strongly held values. Distressingly, Kahan and his colleagues at the Yale Cultural Cognition Project find in a 2011 study that the more scientifically literate you are, the more certain you are that climate change is either a catastrophe or a hoax.
Many science writers and policy wonks believe that fierce disagreement about issues like climate change is simply the consequence of widespread scientific illiteracy. If this thesis of public irrationality was correct, the authors of the Yale study write, “then skepticism about climate change could be traced to poor public comprehension about science” and the solution would be more science education. In fact, the findings of the Yale researchers suggest more education is unlikely to help build consensus; it may even intensify the debate.
To probe the American public's views on climate change, the Yale researchers conducted a survey of 1,500 Americans in which they asked questions designed to uncover their cultural values, their level of scientific literacy, and their thoughts about the risks of climate change.
The group uses a theory of cultural commitments devised by Aaron Wildavsky, which “holds that individuals can be expected to form perceptions of risk that reflect and reinforce values that they share with others.” As noted earlier, the Wildavskyan schema situates Americans' cultural values on two scales, one that ranges from Individualist to Communitarian and another that goes from Hierarchy to Egalitarian. In general, Hierarchical folks prefer a social order where people have clearly defined roles and lines of authority. Egalitarians want to reduce racial, gender, and income inequalities. Individualists expect people to succeed or fail on their own, while Communitarians believe that society is obligated to take care of everyone.
The researchers note that people who hold Individualist/Hierarchical values highly esteem technological innovation, entrepreneurship, and economic growth. Accordingly, they tend to be skeptical of claims about environmental and technological risks and suspect that such claims often amount to little more than unjustifiable excuses for trying to restrict the activities they prize. On the other hand, Egalitarian/Communitarians tend to be morally suspicious of innovation, industry, and commerce, seeing them as the source of unjust disparities in wealth and power. Consequently, they are all too happy to believe claims that those behaviors are risky and impose restrictions on them. In this view, then, Egalitarian/Communitarians would be more worried about climate change risks than Hierarchical/Individualists.
The Yale survey employed a scale in which 1 means no risk and 10 means extreme risk of climate change. The average for the overall sample was a score of 5.7. Hierarchical/Individualists averaged 3.15 points on climate change risk, whereas Egalitarian/Communitarians scored 7.4 on average. The public irrationality thesis predicts that as scientific literacy and numeracy increases, the gap between Hierarchical/Individualists and Egalitarian/Communitarians should lessen. Instead, the Yale researchers found that “among Hierarchical/Individualists science/numeracy is
negatively
[emphasis theirs] correlated with such concern. Hence, cultural polarization actually gets
bigger,
not smaller as science literacy and numeracy increase.”
Why does polarization increase with scientific literacy? “As ordinary members of the public learn more about science and develop a greater facility with numerical information, they become more skillful in seeking out and making sense ofâor if necessary explaining awayâempirical evidence relating to their groups' positions on climate change and other issues,” observe the researchers. Confirmation bias, the tendency to search for or interpret information in a way that confirms one's preconceptions, is ubiquitous.
In addition to climate change risks, the Yale researchers surveyed participants for their views on the safety of nuclear power. In this case, greater scientific literacy was associated with reduced concerns about the risks of nuclear power for both groups. However, the gap in perception about the risks of nuclear power between Hierarchical/Individualists and Egalitarian/Communitarians expanded rather than converged as scientific literacy increased. In other words, as scientific literacy increased, Hierarchical/Individualists became much more comfortable with the risks of nuclear power than Egalitarian/Communitarians did. Again, everybody suffers from confirmation bias.
The Yale researchers chalk up this kind of divergence on technological and scientific risks to the pursuit of individual expressive rationality at the expense of collective welfare rationality. Basically, people in both groups are forming beliefs that advance their personal goals and help them get along with the friends and coworkers they interact with on a daily basis. They illustrate the point by observing that “a Hierarchical Individualist in Oklahoma City who proclaims that he thinks that climate change is a serious and real risk might well be shunned by his coworkers at a local oil refinery; the same might be true for an Egalitarian Communitarian English professor in New York City who reveals to colleagues that she thinks that âscientific consensus' on climate change is a âhoax.'”
Kahan and his colleagues then argue that what is individually rational when it comes to expressing cultural values becomes collectively irrational in the pursuit of policies aimed at securing society members' health, safety, and prosperity based on what the best scientific evidence reveals about risk and risk abatement. In addition, the researchers note, beliefs about the risks of climate change “come to bear meanings congenial to some cultural outlooks but hostile to others.” In this case, Egalitarian/Communitarians, who are generally eager to rein in what they regard as the unjust excesses of technological progress and commerce, see carbon rationing as an effective tool to achieve that goal. This view is distilled in Naomi Klein's book
This Changes Everything: Capitalism vs. the Climate
. Not surprisingly, Hierarchical/Individualists are highly suspicious when proposals involving carbon rationing just happen to fit the cultural values and policy preferences of Egalitarian/Communitarians.
Kahan and his colleagues at the Yale Cultural Cognition Project suggest the Hierarchical/Individualists discount scientific information about climate change because it is strongly associated with the promotion of carbon rationing as the exclusive policy remedy for the problem. They note that other policies that could address climate change might be more acceptable to Hierarchical/Individualistsâfor example, deploying more nuclear power plants, geoengineering, and developing new technologies to adapt to whatever climate change occurs. While the values of Hierarchical/Individualists steer them toward discounting the dangers of climate change, it is also true that the values of Egalitarian/Communitarians push them to magnify any dangers and to discount the risks that top-down policy interventions pose to the economic well-being of society. Confirmation bias is everywhere.
The Cultural Contradiction of Environmentalist Opposition to Nuclear Power
In one of the more aggravating tales of environmentalist self-preening, former activist and now Vermont Law School professor James Gustave Speth details in his book
Red Sky at Morning: America and the Global Environmental Crisis
how he and others managed to stop the development of no-carbon-emitting fast breeder reactors in the 1970s. For example, as a young attorney for the activist Natural Resources Defense Council (which he cofounded) and the Scientists' Institute for Public Information, Speth filed a key 1973 lawsuit against a government plan to commercialize fast breeders.
Fast breeders are nuclear power plants that can produce more fuel (about 30 percent more) than they use. An additional benefit is that they can produce electricity by burning up highly radioactive nuclear waste and the plutonium removed from nuclear weapons. And it gets better: the radioactive wastes generated by fast breeder reactors after their fuel is recycled decays in only a few hundred years instead of the tens of thousands it takes to render the wastes from conventional reactors harmless. Because the reactors produce more fuel than they use, we would not have to mine any more uranium for thousands of years. And new fuel-processing technologies have largely allayed concerns that the plutonium produced by fast reactors could be diverted and used to produce nuclear weapons. In other words, fast breeders might have been the ultimate in renewable energy.
The US government projected that as many as two hundred no-carbon-emitting fast breeder reactors would have been generating power by 2000. No one knows for sure if that projection would have come to pass, but had it done so, current US emissions of carbon dioxide would be roughly a third lower than they are now. Thirty years later in his manifesto, Speth asserts that “the biggest threat to our environment is global climate disruption, and the greatest problem in that context is America's energy use and the policies that undergird it.” The irony of how his youthful opposition to zero-carbon nuclear energy has contributed to the “context of America's energy use” he now decries evidently escapes Speth.
Nuclear power generation is much safer than coal-power generation. Taking occupational deaths and deaths from pollution into account, one rough estimate finds that coal generation kills about 4,000 times more people than does nuclear generation per unit of power. A study by NASA researchers estimated that by displacing coal generation nuclear power avoided somewhere around 1.8 million deaths from air pollution between 1971 and 2009.
There has been a lot of progress in reactor designs since the 1970s. Westinghouse's new AP1000 reactor is chock-full of all sorts of new safety improvements that can shut down a reactor in crisis with no human intervention. Babcock & Wilcox has designed small modular reactors that could be manufactured and fueled at their plant and then taken by rail to be slotted into already built generating facilities. Once the reactor fuel is spent, it is shipped back to the plant for refueling.
Even more intriguing nuclear technologies are thorium reactors and traveling wave reactors. Thorium is a naturally occurring radioactive element that, unlike certain isotopes of uranium, cannot sustain a nuclear chain reaction. It can, however, be doped with enough uranium or plutonium to sustain such a reaction. Fueled by a molten mixture of thorium and uranium dissolved in fluoride salts of lithium and beryllium at atmospheric pressure, liquid fluoride thorium reactors (LFTRs) cannot melt down. (Strictly speaking, the fuel is already melted.)
Because LFTRs operate at atmospheric pressure, they are less likely than conventional pressurized reactors to spew radioactive elements if an accident occurs. In addition, an increase in operating temperature slows down the nuclear chain reaction, stabilizing the reactor. And LFTRs are designed with a salt plug at the bottom that melts if reactor temperatures somehow do rise too high, draining reactor fluid into a containment vessel, where it essentially freezes.
A 2009 NASA report notes that the radioactivity in wastes from LFTRs “would decay to background levels in less than 300 years, as contrasted to over 10,000 years for currently used reactors, thus obviating the need for long term storage, such as at Yucca Mountain.” In fact, LFTRs can burn the long-lived plutonium and other nuclear wastes produced by conventional reactors as fuel, transmuting them into much less radioactive and harmful elements. No commercial thorium reactors currently exist, but China is working on a project that aims to develop them within ten years.