Skip to main content

Thorium nuclear reactor trial begins, could provide cleaner, safer, almost-waste-free energy


At a test site in Norway, Thor Energy has successfully created a thorium nuclear reactor — but not in the sense that most people think of when they hear the word thorium. The Norwegians haven’t solved the energy crisis and global warming in one fell swoop — they haven’t created a cold fusion thorium reactor. What they have done, though, which is still very cool, is use thorium instead of uranium in a conventional nuclear reactor. In one fell swoop, thorium fuel, which is safer, less messy to clean up, and not prone to nuclear weapons proliferation, could quench the complaints of nuclear power critics everywhere.
In a conventional nuclear reactor, enriched uranium fuel is converted into plutonium and small amounts of other transuranic compounds. There are ways to recycle plutonium, but for many countries, such as the USA, it is simply a waste product of nuclear power — a waste product that will be dangerously radioactive for thousands of years. While the safety of nuclear power plants is hotly contested, no one is arguing the nastiness of plutonium. Any technological development that could reduce the production of plutonium, or consume our massive stocks of plutonium waste, would be a huge boon for the Earth’s (and humanity’s) continued well-being. (See: Nuclear power is our only hope, or, the greatest environmentalist hypocrisy of all time.)
Enter thorium. Natural thorium, which is fairly cheap and abundant (more so than uranium), doesn’t contain enough fissile material (thorium-231) to sustain a nuclear chain reaction. By mixing thorium oxide with 10% plutonium oxide, however, criticality is achieved. This fuel, which is called thorium-MOX (mixed-oxide), can then be formed into rods and used in conventional nuclear reactors. Not only does this mean that we can do away with uranium, which is expensive to enrich, dangerous, and leads to nuclear proliferation, but it also means that we finally have an easy way of recycling plutonium. Furthermore, the thorium-MOX fuel cycle produces no new plutonium; it actually reduces the world’s stock of plutonium. Oh, thorium-MOX makes for safer nuclear reactors, too, due to a higher melting point and thermal conductivity.
Thor Energy's thorium reactor in Halden, Norway.
Thor Energy’s thorium reactor in Halden, Norway. The rod in the middle of the picture contains thorium-MOX pellets, and is being inserted into the reactor (which is underground).
Thorium-MOX, in short, is about as exciting as it gets in the nuclear power industry. Before it can be used, though, Thor Energy needs to make sure that the thorium fuel cycle is fully understood. To do this, the company has built a small test reactor in the Norwegian town of Halden, where rods of thorium-MOX provide steam to a nearby paper mill. This reactor will run for five years, after which the fuel will be analyzed to see if it’s ready for commercial reactors. (See: 500MW from half a gram of hydrogen: The hunt for fusion power heats up.)
The first batch of thorium-MOX pellets, which are inside the rods, was made in Germany; the next batch of pelles will be made in Norway; and the final, hopefully commercial-grade pellets will be made by the UK’s National Nuclear Laboratory. Westinghouse Electric Company, one of the world’s largest producers of nuclear reactors, is one of Thor Energy’s commercial backers.
(And yes, just in case you were wondering, the element thorium really is named after Thor, the Norse god of thunder. And yes, Norse mythology originated from Norway, where Thor Energy is based. Coincidence, I think not!)

Comments

Popular posts from this blog

This strange mineral grows on dead bodies and turns them blue

If you were to get up close and personal with Ötzi the Iceman – the 5,000-year-old mummy of a  tattooed ,  deep-voiced  man who died and was frozen in the Alps – you’d notice that his skin is flecked with tiny bits of blue. At first, it would appear that these oddly bluish crystal formations embedded in his skin are from freezing to death or some other sort of trauma, but it’s actually a mineral called  vivianite  (or blue ironstone) and it happens to form quite often on corpses left in iron-rich environments. For Ötzi, the patches of vivianite are  from him resting  near rocks with flecks of iron in them, but other cases are way more severe. According to Chris Drudge at Atlas Obscura , a man named John White was buried in a cast iron coffin back in 1861. During those days, coffins often had a window for grieving family members to peer inside even if the lid was closed during the funeral. Sometime after he was buried, that window broke, allow...

Where the Swastika Was Found 12,000 Years Before Hitler Made Us Uncomfortable About I

Minoan pottery from Crete. The Minoan civilization flourished from 3,000 to 1,100 B.C. (Agon S. Buchholz/Wikimedia Commons) ) Swastika from a 2nd century A.D. Roman mosaic. (Maciej Szczepańczyk/Wikimedia Commons A srivatsa (swastika) sign at Nata-dera Temple, Japan. (Cindy Drukier/Epoch Times) From the Sican/Lambayeque civilization in Peru, which flourished 750 to 1375 A.D. (Wikimedia Commons) Ancient Macedonian helmet with swastika marks, 350-325 B.C., found at Herculanum. (Cabinet des Medailles, Paris/Wikimedia Commons) A Buddha statue on Lantau Island, Hong Kong with a swastika symbol on the chest. (Shutterstock*) A 3,000-year-old necklace found in the Rasht Province of Iran. (Wikimedia Commons) The aviator Matilde Moisant(1878-1964) wearing a swastika medallion in 1912; the symbol was popular as a good luck charm with early aviators. (Wikimedia Commons) A mandala-like swastika, composed of Hebrew letters and surrounded by a circle and a mystica...

20,000 megawatts under the sea: Oceanic steam engines

Jules Verne mused about getting energy from heat in the ocean  (Image: Marc Pagani/Getty) Jules Verne imagined this limitless power source in Victorian times – now 21st-century engineers say heat trapped in the oceans could provide electricity for the world IF ANY energy source is worthy of the name "steampunk", it is surely ocean thermal energy conversion. Victorian-era science fiction? Check: Jules Verne mused about its potential in  Twenty Thousand Leagues Under the Sea  in 1870. Mechanical, vaguely 19th-century technology? Check. Compelling candidate for renewable energy in a post-apocalyptic future? Tick that box as well. Claims for it have certainly been grandiose. In theory, ocean thermal energy conversion (OTEC) could provide  4000 times the world's energy needs in any given year , with neither pollution nor greenhouse gases to show for it. In the real world, however, it has long been written off as impractical. This year, a surprising number of pro...