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14 Mayıs 2014 Çarşamba

Investing in the Future of Thorium-Special Report

Take a look at the word thorium.

What do you see?
Those familiar with Norse mythology or the Marvel comic books might notice the root of the word is Thor, the
name of the god of thunder. Thor is known for his strength and power, wielding a hammer and controlling the
lightning and thunder.

The name alone implies a superhuman power, a superior energy. And the element doesn't disappoint...
Thorium is a radioactive chemical element that can be found in soil and rocks. In its purest form, it appears as a
silver metal, but when heated in the air, it becomes like a white light, like lightning.
Thorium is currently used in things such as light bulbs and camera lenses. It can create a high-quality refractive
glass, and its high melting point can allow ceramics to resist high temperatures.
But light bulbs and ceramics aren’t what have the energy industry watching closely...
Heat resistance is.
You see, thorium’s ultra-high melting point can be useful in more than just ceramics. Heat resistance is
something scientists and energy specialists alike have been trying desperately to achieve with nuclear energy.
One of the biggest issues with nuclear plants is the meltdowns that can occur if the uranium is not cooled
properly. We saw that tragically exhibited in Japan in 2011, when an earthquake and tsunami caused a series of
meltdowns at the Fukushima Daiichi plant. The fact that the only other disaster of that caliber was the 1986
Chernobyl disaster has done little to ease the minds of world governments and energy companies. This simply
highlighted the tragedy that can come along with it.
Which is why thorium’s properties have become so coveted. If the material were virtually meltdown-proof, the
clean energy possibilities would be endless.
There is only one problem: Thorium is unable to sustain a nuclear reaction on its own.
Thorium in Nuclear Energy
Thorium’s inability to sustain a nuclear chain reaction causes a problem, but it’s not one without a solution.
The material can actually prove quite effective when combined with a fissile material — one that is able to sustain
 a nuclear reaction.
These materials include uranium-233 (which is actually an isotope of thorium), enriched uranium (U-235), and
plutonium (Pu-239).
The use of thorium in a nuclear reaction significantly lowers the waste produced; of the waste that does occur,
radioactively decaying elements are lowered as well. Combined with weapons-grade uranium, for instance, one
University of Oslo researcher found that thorium can aid in reducing radioactive waste by up to 95%.
And the safety of a thorium reactor compared to one using uranium is much higher. As mentioned before,
thorium’s high melting point makes a nuclear meltdown much less likely.
But thorium can’t be used in just any nuclear reactor. Only seven types are safe for thorium reactions, including
heavy water reactors, high-temperature gas-cooled reactors, boiling (light) water reactors, pressurized (light)
water reactors, fast neutron reactors, molten salt reactors, and accelerator driven reactors. Molten salt reactors
and accelerator driven reactors are still conceptual, though the other five have all been operational at some
point.
The liquid-fluoride thorium reactor (LFTR), a type of molten salt reactor, is being touted by many as the best
solution to thorium-powered nuclear energy. In these types of reactors, thorium and uranium fluorides are
combined into a salt mixture that’s heated to a molten substance, which is then used to fuel the reactor.
These reactors have the potential to become self-sustainable, as they will be able to produce U-233 (the thorium
isotope).
Flibe Energy, a company started by nuclear technologist and former NASA aerospace engineer Kirk Sorensen,
is conducting research on LFTR technology with a view to eventually incorporate these reactors not just into
electrical energy generation, but also into fields as vastly different as desalination, cancer treatment, and deep
space exploration.
Creating the Nuclear Reaction
Still, the fissile material that enables a thorium reaction is actually fairly difficult to supply...
For years, the U.S. has had a steady stream of U-235 coming in, but that ran out in 2013.
Following the fall of the Soviet Union in 1991 and the Lisbon Protocol in 1992, the U.S. and Russia arrived at the
U.S.-Russian Highly Enriched Uranium Agreement, or what came to be known as the “Megatons to Megawatts
Program.”
Under the terms of the 1993 agreement, Russia would dismantle Soviet nuclear warheads and convert 500
tonnes of highly-enriched uranium to low-enriched uranium, which would be sold to the U.S. for use in nuclear
reactors.
At the end of 2013, ten years after the start of the program, all 500 tonnes had been converted. As a result, the
U.S.’s steady supply of uranium came to a halt.
This affects not just thorium reactors, but currently operational nuclear reactors using uranium as well.
It’s bad news for the U.S. supply, though we can hope the U.S. has found an alternative supply by now. After all,
it’s had ten years to prepare.
If not, expect the price of uranium to jump.
But for thorium, it might not be as bad as it seems. After all, U-235 isn’t the only fissile material that could be
combined with thorium for a nuclear reaction...
U-233, an isotope of thorium, can react with thorium for a nuclear reaction. And this is the focus of the LFTRs, as
it could lead to self-sufficiency of these reactors with the recycled waste.
It’s not easy. Thermal breeding, as the process is called, requires the reactor to produce more fissile material
than it consumes, and it requires a highly specialized type of reactor.
Regular nuclear reactors are unable to breed to the point where it is unnecessary to add more of the fissile
material. But many LFTRs are being designed as breeding reactors. While regularly adding thorium to these
reactors would be necessary, adding U-233 would not. Enough fissile material would be created in the reactions
to sustain it on its own.
Investing
Investing in thorium can be tough, as it’s not yet used for nuclear power generation. Companies like Flibe
Energy, which is focused on thorium reactors, are still private.
But there are several companies working on thorium solutions that you can add to your portfolio...
Lightbridge Corp. (NASDAQ: LTBR)
Lightbridge is working on thorium-based seed & blanket fuel assembly for new and existing reactors. This
technology, which Lightbridge has developed to be compatible with light water reactors, uses “thorium-uranium
oxide pelletized fuel rods similar to that of conventional fuel rods presently used in commercial light water
reactors.”
The difference, the company explains, is that the thorium-uranium oxide will replace the more conventional
uranium oxide.
The company is one of the few publicly traded nuclear fuel technologies companies working with thorium
technology -- which is at its heart, not a proven profit-driver.  Investment in this company relies on a very long
view and a belief in the technology.
In the beginning of 2014, the company received a patent (#8,654,917) for its multi-lobed metallic fuel rod design
and fuel assemblies.  Intellectual property like this adds tangible value to companies dealing with future
technologies.
Uranium Mining Companies
Several uranium miners, like Cameco Corp. (NYSE: CCJ) and Unity Energy Corp. (TSX-V: UTY), are mining
uranium in areas that also have concentrations of thorium.
Though neither company has reported on significant mining of thorium, both are well-positioned to profit should
the demand for the metal skyrocket.
As thorium reactor testing continues in nations like Norway and India, and major investors like Bill Gates (whose
company TerraPower has also begun testing thorium reactors) get involved, attention to the metal will only
grow...
Research on these reactors will lead to implementation, and that will lead to profits for the well-positioned
investor.
Thorium is the nuclear fuel of the future. Keep a close eye on this one.


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