Wednesday 22 August 2012

The Chinese Thorium Programme

On 6th August 2012 Kun Chen, Professor and Deputy Director, Department of Nuclear Safety and Engineering, Shanghai Institute of Applied Physics, Chinese Academy of Sciences, spoke at the Berkeley Department of Nuclear Engineering about the Chinese programme to develop thorium reactors.

In January 2011 the Chinese Academy of Sciences (CAS) launched a Strategic Priority Research Program named“Advanced Fission Energy Program” to confront two grand challenges in the nuclear energy world – long-term nuclear fuel supply and permanent disposal of spent nuclear fuel. 

The program consists of two projects, the TMSR (Thorium Molten Salt Reactor) and an accelerator driven system (the ADS). The TMSR project is to utilize the thorium energy via the development of molten salt and molten salt-cooled reactor technologies, in order to secure the long-term nuclear fuel supply by diversifying the sources of the fuel. By around 2035, the TMSR project will build a 1000 MWe molten salt-cooled demonstration reactor and a 100 MWe molten salt demonstration reactor (liquid fuel), as well as possess the technologies that pave the road to commercialization of the thorium-fuelled nuclear energy systems. The Shanghai Institute of Applied Physics is leading the efforts to build a 2 MW molten salt research reactor in five years. A centre dedicated to TMSR research (TMSR Centre) has already been established.

China has 400 people working on thorium research projects
In the video below (at 09:00) Kun Chen states that with a budget of $70m p.a. there are currently a total of about 400 people working on liquid fuelled molten salt reactors and pebble bed thorium based reactors cooled by molten salt. One of their ambitious targets is to achieve criticality for a 2MW pebble bed thorium based reactor, cooled by molten salt, by the end of 2015. The pre-conceptual design has already been reviewed by a team from Berkeley and the technical design is due to be finished in 2013.

A Liquid Fuelled Reactor by 2017
The schedule for a 2MW liquid fuelled molten salt reactor allows two more years to achieve criticality in 2017, but in answer to the question "What are the biggest challenges to acheiving these targets?" Kun Chen said that the biggest concern is in the choice of materials for the vessel and the heat exchangers. 

In a review of the history of Chinese nuclear research (at 32:30) he also states that from 1970 to 1972 about 500 scientists and engineers worked on an MSR, which was the first Chinese attempt to develop a civilian nuclear power reactor.  At the time they used an aluminium containment vessel, which after a few months was not standing up to conditions. It was decided that they did not have the materials technology to pursue this option and started to develop the LWR instead.


This video was made and posted by Gordon McDowell  it starts with the questions and answers and then goes on to Kun Chen’s presentation.
US Dept of Energy Collaboration with Chinese on Thorium
Mark Halper in his detailed article on smartplanet.com, dated 26th June 2012, reports that the US Department of Energy is collaborating with China on the Molten Salt Reactor project.

But as he states ”What’s not clear is what, exactly, the U.S. will get from the collaboration. While China has declared an interest in building thorium reactors - including CAS’ January 2011 approval of a TMSR project - the U.S. has not. The partnership with China suggests that the U.S. acknowledges a possible role for thorium in its energy future.”
 

Sunday 12 August 2012

Superfuel by Richard Martin

Richard Martin, like many in the Thorium renaissance, is a believer in global warming and sees nuclear power as a way of supplying the world’s base load requirements for energy without adding to global climate change. Furthermore he is clear that the existing first generation of nuclear plants is unsafe and needs to be replaced by inherently safe designs.  He was one of the first journalists to promote thorium in his article in Wired magazine in late 2009.

When you write a book you should always be clear who you are writing it for.  In my view "Superfuel" is not written for the general public.  They would probably find it difficult to follow the vocabulary and the concepts of the nuclear industry, which he doesn’t hesitate to use with little explanation.  Furthermore Martin is a journalist, who uses many words where pictures would be easier to understand, but in "Superfuel" he has included only four diagrams and trying to explain the “Travelling Wave Reactor” in Chapter 8 without a diagram is bound to fail.  

So if he’s not writing to persuade the non-technical public to support the use of thorium and liquid fluoride reactor technologies, does he succeed in developing his argument for the nuclear cognoscenti or even an amateur like me with an engineering background?

Well, yes and no.  His account is superficial and lacking in solid technical detail about his main proposition, thorium fuelled liquid fluoride reactors (LFTR’s).  Aspects of the design that I questioned and needed to understand are not covered, like the treatment of the waste stream and the toxicity of fluorides. There isn’t even a photograph of the Oak Ridge Molten Salt Reactor Experiment to give substance to his frequent assertions about its pioneering advantages.

“Superfuel” also has numerous errors.   For example on page 195 he states “After the Fukushima-Daiichi accident, there was a brief run on supplies of iodine-131. An isotope of iodine produced in specialised reactors, iodine-131 is used to prevent thyroid cancer from radiation exposure.”  In fact it’s potassium iodide which is used to saturate the thyroid gland with iodine and lower the risk of uptake of radioactive iodine-131.

Other examples include stating that Toshiba “is Korean-owned” when it is in fact Japanese.  That, “xenon poisoning” was discovered at the X-10 reactor at Oak Ridge when it was actually first discovered at the Hanford “B” reactor in 1944 and its strongly neutron absorbing properties were easily overcome by adding more fuel rods.
It’s what you would expect from an educated journalist and not a scientist or engineer, so a member of the existing nuclear industry (who Richard Martin labels “the nuclearati”), unfamiliar with liquid fuelled reactors, would never be persuaded.
Where he is at his best is when he does his job as a professional journalist, investigating, sifting the facts and then telling the story, such as in his account of the history of the reasons why the development of civilian nuclear energy went exclusively in the direction of the uranium/plutonium fuel cycle.  More specifically how the light water reactor, with its inherent risk of explosion and release of radioactive materials, came to dominate the commercial market for nuclear power plants. Even here though he is very black and white about the personalities involved and makes little attempt to present a balanced view of, for example, Admiral Hyman Rickover and his achievements or Milton Shaw, who was a pivotal figure in the Atomic Energy Commission when the decision was taken to cancel molten salt reactor research.
Where he has done detailed research such as in chapters 7 and 9, he has turned up organisations and personalities that are retiring and secretive, such as Hector Dauvergne and George Langworth  who did not show up when I did an internet trawl concerning the development of Thorium power for an article that I wrote in September 2011.
In chapter 7 Martin considers the Asian context for nuclear power, and this is also well researched, although clearly access to detailed information sources and policy makers in China has been extremely limited until recently.  India has a huge energy requirement and should be a good candidate for nuclear innovation, but based on the operating performance of their nuclear industry, as quoted in “Superfuel”, they seem to be unable to successfully run their existing nuclear plants, so they cannot be considered as serious candidates to develop LFTR’s.  

Like India, China has a similarly overwhelming need for new energy sources, they have the political conditions for taking risks and they’re not hamstrung by the attitudes arising from 60 years of operation of traditional conventional uranium plants.  They have a highly disciplined technical workforce and experience of stringent quality control.  Furthermore, their regulatory framework is undeveloped compared to the West, and objections are likely to be ignored in the wider public interest.  Finally they have more than enough money to spend!
In Chapter 10 “What we should do?” Martin sets out a plan, from a distinctly US viewpoint, giving ways to fund and conduct a thorium power development programme.  He has researched the numbers and what he proposes would not have been impossible to achieve in a confident US of the 1940’s, 50s or 60’s.  But the US is now a very different country, politically polarised, saddled with a huge and still growing national debt and facing a serious crisis after the next election when they will have to begin to balance the books.   I agree with Richard Martin’s conclusion that China will be the first country to commercialise LFTR technology and, after establishing valid patents, will probably sell it to the West at a price that won’t be matched by any development programme which is started later than theirs!
We can, however, still hope for a breakthrough for Kirk Sorensen with the US military.