Researchers Claim Nuclear Power Has Saved 1.8 Million Lives

Nuclear power. When things go wrong as they have in places like Fukushima and Chernobyl, they get really scary, really fast. 

People die. They get radiation poisoning. 

The damage it wreaks is so unnatural-seeming, it’s the stuff of fantastic sci-fi visions—where irradiated ants grow to size of tanks and hijack Los Angeles; irradiated dead people rise from their graves and eat our entrails.

But as Motherboard’s own Brian Merchant argued last summer, our fears about nuclear fall-out, though grounded in some pretty grizzly reality, want a bit of perspective. 

“Compared to the toll of other energy sources (namely coal),” he writes, "nuclear power’s impact has been relatively benign—with regards to human life, anyways.”

A study published recently in Environmental Science and Technology by scientists at the NASA Goddard Institute for Space Studies and the Columbia University Earth Institute adds heft to that argument, indicating just how much human life nuclear power may have saved over the years. 

To wit, researchers estimate nuclear power has prevented more than 1.8 million deaths due to air pollution between 1971 and 2009.

Given our fears, the findings are counterintuitive. But they're persuasive. 

Those lives were spared, researchers say, because nuclear power spared the earth’s atmosphere 64 gigatons of CO2-equivalent greenhouse gas emissions. 

What’s more, they argue, an additional 80 to 240 gigatons and up to 7 million deaths could be prevented by around 2050 if we replace some of our fossil fuels with nuclear power over time.

There’s a big difference between the estimated 1.8 million from the last 40 years and as many as 7 million in the next 40 years. 

Some of that is attributable to the world’s growing population. 

But some is because the world is industrializing in places like China, where fossil-fuel pollution is a major problem. 

As the graph above indicates, estimated rates of annual lives saved by nuclear power has grown steadily for decades.

As Ben Schiller at Co.Exist explains:

[Study authors] Pushker Kharecha and James Hansen estimate that 4,900 people died as a result of nuclear power between 1971 and 2009, mostly from workplace accidents and radiation fallout, but, they said, 370 times more people (1.84 million) would have died, had we generated the same power from fossil fuels.

The scientists’ figures are based on estimates of mortality caused by particulate pollution, which killed 1.2 million people in China in 2010, according to a recent report. And it gets worse. They say burning natural gas to replace nuclear power will result in at least 420,000 deaths by 2050, and 7 million more if we replace it solely with coal.

Nuclear doesn’t have to be the solution. 

There are plenty of green tech alternatives under development. 

The researchers make it clear, however, that they believe “large-scale expansion of unconstrained natural gas use” would not solve the problem and would “cause far more deaths than expansion of nuclear power.”

Lead image by mbeo via photopin

By Austin Considine 

otherboard.vice.com

Can Small Reactors Ignite a Nuclear Renaissance?

Nuclear option:Babcock & Wilcox’s proposed power plant is based on two small modular nuclear reactors.

Small reactors have some benefits, but they won’t make nuclear as cheap as natural gas.

Small, modular nuclear reactor designs could be relatively cheap to build and safe to operate, and there’s plenty of corporate and government momentum behind a push to develop and license them. But will they be able to offer power cheap enough to compete with natural gas? 

And will they really help revive the moribund nuclear industry in the United States?

Last year, the U.S. Department of Energy announced that it would provide $452 million in grants to companies developing small modular reactors, provided the companies matched the funds (bringing the total to $900 million). In November it announced the first grant winner—Babcock & Wilcox, a maker of reactors for nuclear ships and submarines—and this month it requested applications for a second round of funding. The program funding is expected to be enough to certify two or three designs.

The new funding is on top of the hundreds of millions of dollars Babcock & Wilcox has already spent on developing its 180-megawatt reactor design, along with a test facility to confirm its computer models of the reactor. Several other companies have also invested in small modular reactors, including Holtec, Westinghouse Electric, and the startup NuScale, which is supported by the engineering firm Fluor (see “Small Nukes Get a Boost,” “Small Nuclear Reactors Get a Customer,” and “Giant Holes in the Ground”).

The companies are investing in the technology partly in response to requests from power providers. One utility, Ameren Missouri, the biggest electricity supplier in that state, is working with Westinghouse to help in the certification process for that company’s small reactor design. 

Ameren is particularly worried about potential emissions regulations, because it relies on carbon-intensive coal plants for about 80 percent of its electricity production.

As Ameren anticipates shutting down coal plants, it needs reliable power to replace the baseload electricity they produce. Solar and wind power are intermittent, requiring fossil-fuel backup, notes Pat Cryderman, the manager for nuclear generation development at Ameren. “You’re really building out twice,” he says. That adds to the costs. And burning the backup fuel, natural gas, emits carbon dioxide.

Nuclear reactors that generate over 1,000 megawatts each can cost more than $10 billion to build, an investment that’s extremely risky for a company whose total assets are only $23 billion. 

Power plants based on small modular reactors, which produce roughly 200 to 300 megawatts, are expected to cost only a few billion dollars, a more manageable investment. 

“They’re simply more affordable,” says Robert Rosner, coauthor of a University of Chicago study of potential costs that the DOE has drawn on in evaluating the potential of small reactors.

The smaller size has other potential advantages. Siting a large nuclear power plant can be difficult—it requires, for example, an emergency planning zone extending 10 miles around the plant, Cryderman says. 

That zone could be as small as half a mile for a small modular reactor—in part because of its size and in part because the reactors have added design features. 

For example, while the newest reactors—such as the Westinghouse AP1000—are designed to keep the fuel cool for three days without power, small modular reactors can be designed to go without any power for weeks. He says that if the Nuclear Regulatory Commission approves a smaller emergency planning zone, that could allow Ameren to build nuclear power plants at old coal plant sites, simplifying grid connections and other siting issues.

The smaller size is also an advantage in the United States, where power demand is growing slowly and many utilities don’t want to add multiple gigawatts at a time. 

The modular reactors are expected to take much less time to build as well, so utilities need to forecast demand only a few years out rather than more than a decade, Cryderman says.

Yet questions remain about the viability of small nuclear reactors. While their up-front cost is lower than that of larger reactors, they might prove to cost more per kilowatt of capacity—and per kilowatt-hour of power generated.

Nuclear power plants are built large to achieve economies of scale. 

“Designers could make the reactors put out more power, but they didn’t have to increase the capital costs proportionally,” says John Kelly, deputy assistant secretary for nuclear reactor technologies at the Department of Energy. 

The hope, he says, is that building the reactors in factories will provide an alternative way to reduce costs—through mass production. The small reactors are also simpler in some ways, which can also reduce costs.

But whether those savings will be realized is uncertain. It’s not clear how many reactors need to be built before the potential savings from factory production kick in, and whether there will be enough orders for reactors to hit those numbers. 

For that to happen, Rosner suggests, the government may have to be the first customer, buying the reactors for military bases or government labs.

Even once the final design is approved by the NRC, costs could prove higher than expected once the plants are actually built. 

“Part of the problem when you start in on these things, especially with a new technology, is that all the news after you begin is bad,” says Michael Golay, a professor of nuclear science and engineering at MIT. “Things never behave in an optimized fashion.”

Even if small reactors can compete with conventional nuclear power, they still might not be able to compete with natural-gas power plants, especially in the United States, where natural gas is cheap (see “Safer Nuclear Power, at Half the Price”). 

Their success will depend on how much utilities think they need to hedge against a possible rise in natural-gas prices over the lifetime of a plant—and how much they believe they’ll be required to reduce carbon dioxide emissions.

“At the end of the day, we’ll build the lowest-cost option for ratepayers,” Cryderman says. 

“If it’s too expensive, we won’t build it.” The challenge, he says, is predicting what the lowest-cost options will be over the decades new plants will operate.

Image by The Babcock & Wilcox Company

By Kevin Bullis on March 28, 2013

technologyreview.com