Credit: Justin Randall
What if we could build a nuclear reactor that offered no possibility of a meltdown, generated its power inexpensively, created no weapons-grade by-products, and burnt up existing high-level waste as well as old nuclear weapon stockpiles? And what if the waste produced by such a reactor was radioactive for a mere few hundred years rather than tens of thousands? It may sound too good to be true, but such a reactor is indeed possible, and a number of teams around the world are now working to make it a reality. What makes this incredible reactor so different is its fuel source: thorium.
Named after Thor, the warlike Norse god of thunder, thorium could ironically prove a potent instrument of peace as well as a tool to soothe the world's changing climate. With the demand for energy on the increase around the world, and the implications of climate change beginning to strike home, governments are increasingly considering nuclear power as a possible alternative to burning fossil fuels.
But nuclear power comes with its own challenges. Public concerns over the risk of meltdown, disposal of long-lived and highly toxic radioactive waste, the generation of weapons grade by-products, and their corresponding proliferation risks, all can make nuclear power a big vote-loser.
A thorium reactor is different. And, on paper at least, this radical new technology could be the key to unlocking a new generation of clean and safe nuclear power. It could prove the circuit-breaker to the two most intractable problems of the 21st century: our insatiable thirst for energy, and the warming of the world's climate.
BY THE END OF this century, the average surface temperature across the globe will have risen by at least 1.4˚C, and perhaps as much as 5.8˚C, according to the United Nations Intergovernmental Panel on Climate Change.
That may not sound like much, but small changes in the global average can mask more dramatic localised disruptions in climate.
Some changes will be global: we can expect sea levels to rise by as much as 0.9 metres, effectively rendering a huge proportion of what is now fertile coastal land uninhabitable, flooding low-lying cities and wiping out a swathe of shallow islands worldwide.
The principal culprit is carbon dioxide, a gas that even in quite small quantities can have a dramatic impact on climate, and has historically been present in the Earth's atmosphere at relatively low concentrations.
That was until human activity, including burning fossil fuels, began raising background levels substantially.
Yet while we're bracing ourselves to deal with climate change, we also face soaring demand for more energy - which means burning more fossil fuels and generating more greenhouse gases.
That demand is forecast to boom this century. Energy consumption worldwide is rising fast, partly because we're using much more of it - for air conditioning and computers, for example. In Australia alone, energy consumption jumped by 46 per cent between the mid-1970s and the mid- 1990s where our population grew by just 30 per cent. And energy use is expected to increase another 14 per cent by the end of this decade, according to the Australian Bureau of Statistics. Then there's China, which, along with other fast-growing nations, is developing a rapacious appetite for power to feed its booming economy.
And fossil fuels won't last forever. Current predictions are that we may reach the point of peak production for oil and natural gas within the next decade - after which production levels will continually decline worldwide.
That's if we haven't hit the 'peak oil' mark already. That means prices will rise, as they have already started to do: cheap oil has become as much a part of history as bell-bottomed trousers and the Concorde.
Even coal, currently the world's favourite source of electricity generation, is in limited supply. The U.S. Department of Energy suggests that at current levels of consumption, the world's coal reserves could last around 285 years. That sounds like breathing room: but it doesn't take into account increased usage resulting from the lack of other fossil fuels, or from an increase in population and energy consumption worldwide.
According to the U.S. Energy Information Administration, as of 2003, coal provided about 40 per cent of the world's electricity - compared to about 20 per cent for natural gas, nuclear power and renewable sources respectively. In Australia, coal contributes even more: around 83 per cent of electricity.
This is because coal is abundant and cheap, especially in Australia. And although a coal-fired power plant can cost as much as A$1 billion (US$744 million) to build, coal has a long history of use in Australia. Coal is also readily portable, much more so than natural gas, for example - which makes it an excellent export product for countries rich in coal, and an economical import for coal-barren lands.
But the official figures on the cost of coal don't tell the whole story. Coal is a killer: a more profligate one than you would expect.
And it maintains a lethal efficacy across its entire lifecycle.
One of the main objections held against nuclear power is its potential to take lives in the event of a reactor meltdown, such as occurred at Chernobyl in 1986. While such threats are real for conventional reactors, the fact remains that nuclear power - over the 55 years since it first generated electricity in 1951 - has caused only a fraction of the deaths coal causes every week.
Take coal mining, which kills more than 10,000 people a year. Admittedly, a startling proportion of these deaths occur in mines in China and the developing world, where safety conditions are reminiscent of the preunionised days of the early 20th century in the United States. But it still kills in wealthy countries; witness the death of 18 miners in West Virginia, USA, earlier this year.
But coal deaths don't just come from mining; they come from burning it. The Earth Policy Institute in Washington DC - a nonprofit research group founded by influential environmental analyst Lester R. Brown - estimates that air pollution from coal-fired power plants causes 23,600 U.S. deaths per year. It's also responsible for 554,000 asthma attacks, 16,200 cases of chronic bronchitis, and 38,200 non-fatal heart attacks annually.
The U.S. health bill from coal use could be up to US$160 billion annually, says the institute.
Coal is also radioactive: most coal is laced with traces of a wide range of other elements, including radioactive isotopes such as uranium and thorium, and their decay products, radium and radon. Some of the lighter radioactive particles, such as radon gas, are shed into the atmosphere during combustion, but the majority remain in the waste product - coal ash.
People can be exposed to its radiation when coal ash is stored or transported from the power plant or used in manufacture of concrete. And there are far less precautions taken to prevent radiation escaping from coal ash than from even low-level nuclear waste. In fact, the Oak Ridge National Laboratory in the U.S. estimates the amount of exposure to radiation from living near a coal-fired power plant could be several times higher than living a comparable distance from a nuclear reactor.
Then there are the deaths that are likely to occur from falling crop yields, more intense flooding and the displacement of coastal communities which are all predicted to ensue from global warming and rising oceans.
There's so much heat already trapped in the atmosphere from a century of greenhouse gases that some of these effects are likely to occur even if all coal-fired power plants were closed tomorrow. Whichever way you look at it, coal is not the smartest form of energy.
perplexed
Every energy form of energy generation has some impact on the environment. Thorium waste is about as radioactive as coal ash - the latter of which is not regulated, and just buried in landfill. Oh, and coal particulate emissions kill a couple of hundred thousand people every year. yet coal is the #1 form of energy we use.
There's no perfect form of baseload energy. It's just which is better.
Sam
Solar, nuclear
Hiya. Another option for the inherent burstiness of solar: the Solar Grand Plan published in Scientific American (http://www.sciam.com/article.cfm?id=a-solar-grand-plan). They propose storage of the energy as compressed air underground, in the same kind of natural spaces as natural gas reserves. All the tech in there is commercial-grade proven now (doesn't assume technological breakthroughs or lab-grade efficiencies) and allows for year-on-year increase in consumption. The assumption is landmass for solar panels, which Australia has in abundance.
The thorium idea sounds good for disposal of existing plutonium stocks, though.
Molten salt reactors
There is a third alternative - the Liquid Fluoride Thorium Reactor. The liquid form of fuel allows the immediate removal of neutron-absorbing fission products like xenon gas. This improves neutron efficiency and allows the reactor to sustain the reaction without any external help in the form of a particle accelerator or other fissile materials.
This type of reactor is also meltdown-proof. If it heats up the liquid expands, reducing the reactivity. This creates a robust self-regulating effect where the reactor generates exactly the same amount of heat that is removed from the core for power generation. The liquid fluoride fuel form remains liquid even under extreme temperatures without boiling. This allows the reactor to run at atmospheric pressure, making it much safer than current high-pressure water cooled reactors.
Instead invest into fusion.
Instead invest into fusion. There are many alternative designs than the notorious Tokamak, some of which are already tested to produce much more than break-even. Fusion byproducts do not last for centuries, if a right reaction is chosen the decay time is likely to be less than a day. It can be much smaller, safer and cheaper to operate than a nuclear reactor.
One of the most simple, cheapest and safest of possible concepts is promoted by www,focusfusion.org . Estimated 5 million to research, 5 million to build prototype in less than 10 years.
You state that the Thorium
You state that the Thorium can't sustain a chain reaction on its own, because the U-233 doesn't pump out enough neutrons to sustain the chain reaction. That's not true for the molten salt reactor you discuss. U-233 produces something like 2.4 neutrons on average in a low-speed (a.k.a. thermal) fission. 1 of those sustains the chain reaction, 1 is used to convert Th-232 to Th-233 and thence to U-233, leaving 0.4 to be wasted.
Thorium Power Inc is proposing to put solid-phase thorium oxide fuel into pressurized water reactors. In this configuration, more than 0.4 neutrons from every U-233 fission will end up absorbed somewhere unhelpful, and the Thorium fuel rod needs something else to boost the reactivity so that it sustains the chain reaction. Pu-239 works well.
In the molten salt reactor, which you discuss, there are fewer things to absorb the neutrons (less structure, no coolant water, and fewer fission products), so the reactor can break even without help from the Pu-239. So your statement is a misinterpretation and a bit confusing.
It is the ability of molten salt reactors to seperate fission products from fuel while operating that makes it possible for them to burn all their actinides, and thus have shorter-term waste. This aspect attracts me to the design most of all.
gabble
gubbhish gabble gobbish gubble
No comparison between coal and nuclear.
Not very smart or logical.
You compare coal deaths to nuclear deaths.
Coal doesn't have a half-life of when it emits a less deadly radiation.
Coal doesn't seep into the groundwater and then irradiate you and your children for the REST OF YOUR LIFE, IF YOU LIVE THROUGH IT!!!
Ignorant, ignorant, ignorant.
Don't you dare compare the two- nuclear is way worse, even though coal is destructive and dirty as hell and should not be used as a power source.
Coal doesn't require storage of spent rods that any mathematician worth his salt will tell you is an equation of death waiting to happen- it's just a question of WHEN.
Grow Up
Urainum and thorium litter every coal fired plant in the world. The dirty little secret is that there are no requirements contain these elements as with the good stewards who work at nuclear power facilities. So if you're worried about radioactive elements seeping into you life it is likely that they already have seeing that you have the argument backward. It's best to do some homework first.
Small Thorium plants have a huge potential market.
The market for a small and safe nuclear powerplant is huge, but it is easy to forget these posibilities. The realy good thing about thorium powerplants is that they can be build very small and safe. So small that you can fit them in airplanes. Not that i would want a thousand flying nuclear powerplants over my head, but it would revolutionize shipping. A small, efficient and encapsuled reactor would be perfect, not only for ships but cities, islands and even future ekranoplanes. It is realy sad that the USA stopped the development of Molten-salt Fueled Reactors in the middle of the 1970s, and this world have been slaves to oil far to long. Count Norway out of it. Norwegian politicians are like syrup. A sticky and slow mass that don't move much at all. The market is out there, no doubts about that. Honestly, what ever country or company that solve the problems, are going to end up very wealthy.
Alekssander ,Norway
(Tired of syrup politicians.)
Options
Thorium seems more promising short term than fusion.
Renewable energy, best I can see is combo of wind/solar *and* biomass such as wood, veg oil. To succeed with this people would also need to consume *less* energy.
It only really takes 1 hp/750 watts to propell you at up to 60 mph/100 km/h in a velomobile. Similarly, only a small amount of energy is required to heat a small living space of a modest home to room temp, the rest of house/storage could stay at just above freezing during coldest winters.
We could easily design a comfortable life around 1/4 of the energy we now consume.