Liquid Fluoride Thorium Reactor

In summary, the Liquid Fluoride Thorium Reactor (LFTR) is an attractive concept that faces many challenges before it can be implemented on a large scale. If scaled up, it may be impractical due to corrosion, creep and creep fatigue. There are modern concepts for the Molten Salt Reactor, but they are more expensive and would require special regulations for handling of fission products.
  • #106
Any energy source is finite (see elemental thermodynamics). Thorium will easily last for tens of thousands of years, consume long lasting TRU waste, and produce on-demand energy without emissions of any air pollution or green house gases. I'd say that is good enough.
I have some doubts on tens of thousand years.Sounds too good to be true.
Wikipedia gives us info that total extractable world Thorium reserves are estimated at 1 million 600 thousands of tons. http://en.wikipedia.org/wiki/ThoriumIf we divide this number per 7 billions of modern human on Earth inhabitants,we receive weight less than 200 grams per person.
Are they going to tell that if Thorium will be main and primary energy source for humans it will last more than one generation?I have doubts on it...

One more problem: In currently proposed designs of LFTR they suppose to use Liquid FLiBe salt http://en.wikipedia.org/wiki/Liquid_fluoride_thorium_reactorSo it will require tons of Lithium and Berillium per reactor.Berillium is even much rare than Thorium.And needed for many critical apps.Neither Thorium or Berillium are present in salt water.
 
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  • #107
If completely burned in a reactor, 200 grams of Th would yield 10 kW of thermal power, the US average power use per capita, for ~53 years. There is a great deal of Th mass in the oceans, not counted in those land based reserve figures. I see a source show 10pg/ml Th in ocean water, or 13.4 million tonnes total.The only material that would be consumed in such a reactor is the Th. Other supporting materials can be reused.
 
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  • #108
Stanley514 said:
I have some doubts on tens of thousand years.Sounds too good to be true.
Wikipedia gives us info that total extractable world Thorium reserves are estimated at 1 million 600 thousands of tons. http://en.wikipedia.org/wiki/ThoriumIf we divide this number per 7 billions of modern human on Earth inhabitants,we receive weight less than 200 grams per person.
Are they going to tell that if Thorium will be main and primary energy source for humans it will last more than one generation?I have doubts on it...

One more problem: In currently proposed designs of LFTR they suppose to use Liquid FLiBe salt http://en.wikipedia.org/wiki/Liquid_fluoride_thorium_reactorSo it will require tons of Lithium and Berillium per reactor.Berillium is even much rare than Thorium.And needed for many critical apps.Neither Thorium or Berillium are present in salt water.

Thorium resources are likely to be vastly greater that currently estimated, as it has not been much in demand historically. Moreover, most of the current supply is afaik as a byproduct of rare Earth mining, where thorium is an unwanted contaminant. So our current resource estimate is really an estimate of waste product abundance.

Beryllium however is another matter. It is a pretty rare mineral in any of its forms, with no large resource anywhere afaik.
 
  • #109
Stanley514 said:
I have some doubts on tens of thousand years.Sounds too good to be true.
Wikipedia gives us info that total extractable world Thorium reserves are estimated at 1 million 600 thousands of tons. http://en.wikipedia.org/wiki/ThoriumIf we divide this number per 7 billions of modern human on Earth inhabitants,we receive weight less than 200 grams per person.
Are they going to tell that if Thorium will be main and primary energy source for humans it will last more than one generation?I have doubts on it...

One more problem: In currently proposed designs of LFTR they suppose to use Liquid FLiBe salt http://en.wikipedia.org/wiki/Liquid_fluoride_thorium_reactorSo it will require tons of Lithium and Berillium per reactor.Berillium is even much rare than Thorium.And needed for many critical apps.Neither Thorium or Berillium are present in salt water.

There is far more than 1 600 000 tonnes of recoverable Th in the Earths crust. Those numbers refer only to estimated amount in presently known high quality reserves on dry land - easily accessible thorium mineral deposits recoverable at price below X. And considering we have not even seriously looked for thorium, it is probably a gross understatement of real world reserves.

And we can also use far lower quality reserves for LFTR, since thorium fuel price is negligible compared to the value of generated electricity and reactor costs. Even the method advocated by Weinberg - "burning the rocks" - extracting thorium from ordinary soil, has favorable EROEI (energy returned on energy invested), since thorium atom is so energy dense and LFTR uses 99% of the Th fuel, instead of 1% of uranium fuel as ordinary nuclear power plants.

There were threads about this on Energyfromthorium.com forum:
http://www.energyfromthorium.com/forum/viewtopic.php?f=2&t=3398 [Broken]
http://www.energyfromthorium.com/forum/viewtopic.php?f=2&t=3512
http://energyfromthorium.com/2006/04/29/how-much-thorium-would-it-take-to-power-the-whole-world/
 
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  • #110
There is a great deal of Th mass in the oceans, not counted in those land based reserve figures. I see a source show 10pg/ml Th in ocean water, or 13.4 million tonnes total.
Concentration of Thorium in seawater is negligibly small,something like
0.0000004 ppm.This is a million times more rare than Uranium.
http://mistupid.com/chemistry/seawatercomp.htm
I guess it would be no practically to retreive it, for sure.

It would be interesting what chemical elements beside Thorium could be used as a fertile
nuclear fuel.Theoretically any element which is havier than Iron could be used to get energy by fission.What about Tungsten?

It would be bigger success if they would manage to get energy from Boron.Such as in fusion reactions.There is 6 trillions of tons of Boron in seawater and it could be retrieved at competitive price already now.
 
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  • #111
Stanley514 said:
Concentration of Thorium in seawater is negligibly small,something like
0.0000004 ppm.This is a million times more rare than Uranium.
http://mistupid.com/chemistry/seawatercomp.htm
I guess it would be no practically to retreive it, for sure.
The Th concentration figure from my reference has a concentration 25X higher than yours in seawater, and Uranium at 4ppb in seawater is 300X higher than Thorium (my reference) in seawater. At that concentration (10pg/ml), 100k cubic meters (100e6 liters) of seawater are required to produce a gram of Th, which as we know produces 1MW-day of heat energy in a reactor. Is that practical? I dunno.

It would be interesting what chemical elements beside Thorium could be used as a fertile
nuclear fuel.Theoretically any element which is havier than Iron could be used to get energy by fission.What about Tungsten?
I don't think net energy is possible with any of the other natural elements besides the the traditional fertile isotopes of thorium and uranium (Th232, U234&238). The problem with using anything else is the process results in a net loss of neutrons. Unless I've missed something*, once all of the U and Th is gone, along with any transuranics made by U and Th, i.e. Pu, then net energy fission is done on this planet.

*I suppose there's always high Z fusion to build it all back up again, but so far that requires a supernova.
 
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  • #112
Stanley514 said:
I have some doubts on tens of thousand years.Sounds too good to be true.
Wikipedia gives us info that total extractable world Thorium reserves are estimated at 1 million 600 thousands of tons. http://en.wikipedia.org/wiki/ThoriumIf we divide this number per 7 billions of modern human on Earth inhabitants,we receive weight less than 200 grams per person.
...
oh, as others have pointed out, that figure refers to reserves, i.e. go to spot X,dig to depth Y, and it is likely that Z tons of Thorium will be found there. As to the total mass of Th on earth, Th is estimated to be 1.5e-5 of the total mass of the earth, ie 15 ppm, or 9 million billion tons.
 
  • #113
Unless I've missed something*, once all of the U and Th is gone, along with any transuranics made by U and Th, i.e. Pu, then net energy fission is done on this planet.
It is said that one of major constituents of geothermal heat is Potassium-40.
Could we use this element as a fertile fuel somehow?
 
  • #114
The heat from P40 is decay heat, not nuclear fission.
 
  • #115
A simple search in Bing brings up an excellent summary from the World Nuclear Association here: http://www.eoearth.org/article/Thorium

The punch line in terms of the resource is in the summary of pros and cons:
' The main attractive features are:
• the possibility of utilising a very abundant resource which has hitherto been of so little interest that it has never been quantified properly,
• the production of power with few long-lived transuranic elements in the waste,
• reduced radioactive wastes generally. '

So we don't know how much thorium is to be found because we've never looked.
We do know it is several times more abundant than Uranium and a vastly better burn up fuel.
Surely that is enough to at least work the problem, even if the resource is not a solution for all time.
 
  • #116
etudiant said:
A simple search in Bing brings up an excellent summary from the World Nuclear Association here: http://www.eoearth.org/article/Thorium

The punch line in terms of the resource is in the summary of pros and cons:
' The main attractive features are:
• the possibility of utilising a very abundant resource which has hitherto been of so little interest that it has never been quantified properly,
• the production of power with few long-lived transuranic elements in the waste,
• reduced radioactive wastes generally. '

So we don't know how much thorium is to be found because we've never looked.
We do know it is several times more abundant than Uranium and a vastly better burn up fuel.
Surely that is enough to at least work the problem, even if the resource is not a solution for all time.
Those are the strong points of the fuel cycle, but I think they are secondary to the reactor fail-safe advantages gain by operating a molten salt reactor, finally providing a path to eliminate 300 atm pressurized water and all that goes with it.
 
  • #117
mheslep said:
Those are the strong points of the fuel cycle, but I think they are secondary to the reactor fail-safe advantages gain by operating a molten salt reactor, finally providing a path to eliminate 300 atm pressurized water and all that goes with it.

Correct me if I am wrong, but is there not a secondary cooling loop which uses water, in all MSR designs? How does this constitute "eliminating" it?

I don't think using thorium is a bad idea per se, it's just that I think mixing two un-proven technologies (MSR and HEU-initiated thorium cycle) is not so safe. The Indian approach of modifying the well-known and long-proven CANDU design (for all its flaws) seems to be lower risk. Better the devil we know.
 
  • #118
mheslep said:
I don't think net energy is possible with any of the other natural elements besides the the traditional fertile isotopes of thorium and uranium (Th232, U234&238). The problem with using anything else is the process results in a net loss of neutrons. Unless I've missed something*, once all of the U and Th is gone, along with any transuranics made by U and Th, i.e. Pu, then net energy fission is done on this planet.

Why? If you have a reasonable way to produce the required neutrons (such as fusion), you can split atoms all you like, for a net gain in energy. The reaction is not self-sustaining in bulk, is all.
 
  • #119
zapperzero said:
Why? If you have a reasonable way to produce the required neutrons (such as fusion), you can split atoms all you like, for a net gain in energy. The reaction is not self-sustaining in bulk, is all.
Not for most nuclei.

The Russians have some data on fission of Rn(Z=86)-222, and the cross-section are quite low. One would more likely get an (n, n') or (n,#n) reaction, or some other spallation reaction. They also indicate no fission for Po isotopes, or the cross-sections are so low compared to other spallation reactions that one cannont measure any discernible fission event. Other countries don't have any data regarding fission of isotopes below Ra-223.

http://www.nndc.bnl.gov/sigma/getPlot.jsp?evalid=12956&mf=3&mt=18&nsub=10

See - σ(n,F) - at http://www.nndc.bnl.gov/chart/reCenter.jsp?z=83&n=126 - and select Zoom 5 to see readily fissionable isotopes (that is with thermal neutrons). The lightest is Ra-223 and that has very low cross-section.

For a closer look - http://www.nndc.bnl.gov/chart/reCenter.jsp?z=88&n=135 (Zoom 4) and make sure one picks σ(n,F) at the top bar.
 
  • #120
The question was not about the fission likelihood of elements other than U and Pu, but could lesser elements be built up to heavy through repetitive neutron capture and beta decay to arrive at U or Pu the way Thorium can be from a single neutron, i.e. breeding fissionable materials from fertile elements. Clearly this doesn't work in a fission reactor, in which case every neutron captured loses a potential ~200MeV.

I had not considered using the neutrons from a fusion reactor as ZZ suggests, but I see at least two problems with that approach: i) even in neutronic fusion, those neutrons are required to breed tritium in a net energy reactor, i.e. like fission a neutron wasted to build heavy elements wastes a potential 17MeV from making tritium. ii)I have no idea of the cross section and beta decay chain that might be required to breed, say Si into U, or if it is possible without regard to energy. I'd guess somewhere along the way there will no beta decay 'step up' available, only alpha to go down. But without researching the issue, IF the cross section decay chain was advantageous for neutron absorption all the way up to U and Th, I think we would see the production of those elements in stars like ours. We don't, short of heavy element fusion in novae.
 
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  • #121
zapperzero said:
Correct me if I am wrong, but is there not a secondary cooling loop which uses water, in all MSR designs? How does this constitute "eliminating" it?
Could be water or helium gas. Most of the design design discussions focus on gas so they can go Brayton.

In any case the point is not the nature of the cooling loop, but that in an MSR the cooling loop is not needed to prevent catastrophe. The cooling loop could be turned off, lose power, be destroyed by an airplane, and there's no chance of a leak of 300atm water, then flashing to steam, expanding several orders of magnitude trying to escape containment to the outside world. Instead, a frozen plug of salt melts, draining the reactor salt by gravity into a tank where further criticality is impossible and decay heat is not a problem. Furthermore, when the cooling loop power is returned or rebuilt, there's no commercial loss, as the reactor salt is heated and pumped back into the reactor. This event happened several times with the MSR built at Oak Ridge.
 
  • #122
mheslep said:
Could be water or helium gas. Most of the design design discussions focus on gas so they can go Brayton.

Gas sounds more reasonable. I didn't know that.
 
  • #123
FYI - Antonio Cammi, Valentino Di Marcello, Lelio Luzzi, Vito Memoli, Marco Enrico Ricotti, A multi-physics modelling approach to the dynamics of Molten Salt Reactors, Annals of Nuclear Energy, Volume 38, Issue 6, June 2011, Pages 1356-1372, ISSN 0306-4549, 10.1016/j.anucene.2011.01.037.
(http://www.sciencedirect.com/science/article/pii/S0306454911000582)
Keywords: Molten Salt Reactor; Multi-physics modelling; Thermo-hydrodynamics; Reactor dynamics

Abstract
This paper presents a multi-physics modelling (MPM) approach developed for the study of the dynamics of the Molten Salt Reactor (MSR), which has been reconsidered as one of the future nuclear power plants in the framework of the Generation IV International Forum for its several potentialities. The proposed multi-physics modelling is aimed at the description of the coupling between heat transfer, fluid dynamics and neutronics characteristics in a typical MSR core channel, taking into account the spatial effects of the most relevant physical quantities. In particular, as far as molten salt thermo-hydrodynamics is concerned, Navier–Stokes equations are used with the turbulence treatment according to the RANS (Reynolds Averaged Navier–Stokes) scheme, while the heat transfer is taken into account through the energy balance equations for the fuel salt and the graphite. As far as neutronics is concerned, the two-group diffusion theory is adopted, where the group constants (computed by means of the neutron transport code NEWT of SCALE 5.1) are included into the model in order to describe the neutron flux and the delayed neutron precursor distributions, the system time constants, and the temperature feedback effects of both graphite and fuel salt. The developed MPM approach is implemented in the unified simulation environment offered by COMSOL Multiphysics®, and is applied to study the behaviour of the system in steady-state conditions and under several transients (i.e., reactivity insertion due to control rod movements, fuel mass flow rate variations due to the change of the pump working conditions, presence of periodic perturbations), pointing out some advantages offered with respect to the conventional approaches employed in literature for the MSRs.
 
  • #124
Astronuc said:
FYI - Antonio Cammi, Valentino Di Marcello, Lelio Luzzi, Vito Memoli, Marco Enrico Ricotti, A multi-physics modelling approach to the dynamics of Molten Salt Reactors, Annals of Nuclear Energy, Volume 38, Issue 6, June 2011, Pages 1356-1372, ISSN 0306-4549, 10.1016/j.anucene.2011.01.037.
(http://www.sciencedirect.com/science/article/pii/S0306454911000582)
Keywords: Molten Salt Reactor; Multi-physics modelling; Thermo-hydrodynamics; Reactor dynamics

Thanks! A modern model in the literature, vice on a pop web site, is overdue.
 
  • #125
zapperzero said:
Correct me if I am wrong, but is there not a secondary cooling loop which uses water, in all MSR designs? How does this constitute "eliminating" it?

I don't think using thorium is a bad idea per se, it's just that I think mixing two un-proven technologies (MSR and HEU-initiated thorium cycle) is not so safe. The Indian approach of modifying the well-known and long-proven CANDU design (for all its flaws) seems to be lower risk. Better the devil we know.

Because you are using the reaction mass itself as your primary cooling loop, and it is liquid salts, you have very low pressure, basically just the pressure required for moving the fluid.

The heat exchangers, even if they run dry on the secondary side, they will still be safe, and thus can use the much more efficient single pass heat exchangers, which were banned from PWR use after TMI. In TMi the loss of heat take-off caused the core to melt, but in a MSR, the core is already and intentionally melted.

And no, the technology is proven, just not developed. ORNL's LFTR program proved that the system was able to make thermal power, which is all you need from a NSSS.

A layman should read http://home.earthlink.net/~bhoglund/mSR_Adventure.html to get an idea of what was done, and why it stopped.
 
  • #126
That ORNL reactor simulated the idea starting with U233; it never used Thorium, so the Protactinium did not have to be chemically removed while it decayed to U233. There's still a bit of proving to do yet.
 
  • #127
Even a MSR reactor core need to be cooled. If the primary cooling loop fails it needs a secondary way to cool. This can be dumping the core into a dump tank that is cool by passive means.
 
  • #128
If people would be able to tap geothermal energy properly
there would be no need in nuclear reactors.There is giant ocean
of magma under our feet.But I think it would require some other
cycle than water cycle.Maybe some electron or thermoelectric cycle?
Earth crust has its own electric charge and should behaive like
thermoelectric?
 
  • #129
Stanley514 said:
If people would be able to tap geothermal energy properly
there would be no need in nuclear reactors.There is giant ocean
of magma under our feet.But I think it would require some other
cycle than water cycle.Maybe some electron or thermoelectric cycle?
Earth crust has its own electric charge and should behaive like
thermoelectric?

Based on the geothermal record to date, 'unblemished by success', your reservations about a geothermally powered water cycle may be apprpriate.
However, no other approach is even at the proof of principle level afaik, so the water cycle is pretty much the only game in town for the next decade or so.
Given the scale of the energy needs, it is hard to take untested approaches seriously.
 
  • #130
I do not claim it is seriously but I think insted of water could be used for example Sulfur.It`s boiling point is higher and it possible could give you higher energy density.
Also Earth is known as a good conductor.There is natural thermoelectric currents in Earth which result in magnetic field and Telluric currents which could be registered.I want to know if heat could be transferred through some kind of electric resonance?For example we have hot body which is in electric resonance with cold body.There is some electric resonance beween them.Could it work similar to thermopower?
 
  • #131
Stanley514 said:
I do not claim it is seriously but I think insted of water could be used for example Sulfur.It`s boiling point is higher and it possible could give you higher energy density.
Also Earth is known as a good conductor.There is natural thermoelectric currents in Earth which result in magnetic field and Telluric currents which could be registered.I want to know if heat could be transferred through some kind of electric resonance?For example we have hot body which is in electric resonance with cold body.There is some electric resonance beween them.Could it work similar to thermopower?

You're dealing with insights I don't have.
What is a 'telluric current' or an 'electric resonance'?
Presently, I'm unaware of any demonstrated example of power generation from any Earth currents or magnetic fields. I'd be keenly interested if there is any data available.
Sulfur does indeed have a higher boiling point, but also has very little extra heat capacity in the sulfur vapor, so extracting energy from a sulfur turbine is a bear. Sulfur also has all the reactive capacity of hot oxygen, so it is a material that is not to be trifled with.
Warts and all, water is a lot easier to deal with.
 
  • #132
  • #133
Stanley514 said:
Some inventors patented Alpha decay stimulator with help of
Van Der Graaf generator.http://www.freepatentsonline.com/5076971.html If it comes true
then aneutronic fission reactor would be possible.
Alpha decay is unrelated to fission, and in any case has nothing to do with this thread on LFTRs.
 
  • #134
Stanley514 said:
Some inventors patented Alpha decay stimulator with help of
Van Der Graaf generator.http://www.freepatentsonline.com/5076971.html If it comes true
then aneutronic fission reactor would be possible.
As far as I can tell, the patent refers to a more rapid transmutation or decay process, not aneutronic fission. Alpha emission is a decay process; it is not fission. Many radionuclides heavier than lead undergo alpha decay. Far fewer nuclides are fissile.
 
  • #135
Alpha decay is unrelated to fission, and in any case has nothing to do with this thread on LFTRs.
I think that any technology that is designed to be directly competing with LFTR and allows to undestand competitiveness of LFTR has right to be discussed here.I do not care if it is fission or decay,the most important if it is able to produce lot of net energy by decay.
 
  • #136
If the proposed method with Thorium decay stimulation will
succeed and generate net power then it will have following advantages
over LFTR:

1)No neutron radiation is created during all stages of the process.Though some low energy gamma radiation may be result of decay.
2)No Uranium 235 as a kindler is requiered.
3)No long lived isotopes are created.
4)Possibly no any radioactive waste is created as a result of the process.
5)No molten salts are requiered and therefore corrosion is reduced or eliminated.
 
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  • #137
Stanley514 said:
If the proposed method with Thorium decay stimulation will
succeed and generate net power then it will have following advantages
over LFTR:

...
5)No molten salts are requiered and therefore corrosion is reduced or eliminated.

Thorium decay is proposed as method for commercial power generation? What is the proposed power density? One of the advantages of using molten salts is to move away from pressurized containment in the primary and the consequences of leaving solid fuel uncooled. If the power density is trivial then the problem solves itself without resort to molten fuels.
 
  • #138
Thorium decay is proposed as method for commercial power generation? What is the proposed power density?
First of all an effect that they claim to exist still have to be proved.In their patent (?) they claim that many successful experiments been conducted.But in the same time I didn`t read in other sources information that nuclear decay rates could be drastically enhanced with help of common Van-der-Graaf machine.
What is concerning power density I don`t know. For example they make statement like:
The Van de Graaff voltage φ ignites radioactive waste. If the burn is going too slowly, re-ignite with an eφΔt less than the initial value. High voltages may be hazardous. For example. φ=2 MV predicted to convert the half-life of U238 to one second. Before initiating a decontamination procedure, the composition of the fuel should be determined.
Looks like a new way to create a nuclear explosive device...
 
  • #139
Stanley514 said:
First of all an effect that they claim to exist still have to be proved.In their patent (?) they claim that many successful experiments been conducted.But in the same time I didn`t read in other sources information that nuclear decay rates could be drastically enhanced with help of common Van-der-Graaf machine.
What is concerning power density I don`t know. For example they make statement like:
Looks like a new way to create a nuclear explosive device...

The half life reductions actually achieved in the paper are very small, at the experimental error level really.
So I would be hesitant to accept the kind of huge reductions suggested in the analysis, at least not until some more convincing experimental evidence is forthcoming.
That said, there are active proposals to use thorium fuel bundles in conventional LWRs, based on a lot of solid work done in Russia.
However, these have none of the more speculative elements suggested above, where thorium is burnt down to a few residual short lived actinides. Absent demonstration, it is unwise to rely on such pie in the sky projections.
They remind me altogether too much of the Reagan era NASP, a proposed aerospace plane that would take off and fly to orbital speed. The theory was compelling, the engineering a nightmare. They quit when the design had gone from 50,000 pounds to 1 million pounds, with cost increases to match.
 
  • #140
The half life reductions actually achieved in the paper are very small
The claimed reductions do not seem to be really small.
Tests were conducted to show that a positive or negative voltage on a Van de Graaff generator accelerates beta and alpha decay. One beta and two alpha emitters were placed inside the generator sphere, charged to a voltage of 350+75 kv, for a period of twelve hours. When the voltage was switched off, the measured activity oscillated through substantial variations. After three days the measured depletion was about 1% for Tl 204, about 7% for Po 210 and about 2.6% for Th 230. After seven days, the depletion had increased to about 5.3%, about 55.3% and about 81.8%, respectively. It is expected that the depletion will continue to background for all three sources within about 60 days.
If under depletion they mean that few percents of nuclear fuel decayed in few days then it is very significant reduction.For example half-life of Th 230 is 75.000 of years.
Also as I could understand from their claims the higher voltage means better rate reductions.With modern technologies there is no problem to create static electric field up to billions of volts.For exaple tabletop pyroelectric fusion device is claimed to create 25 gigavolts per meter.I think this effect could be easily verified if it exists.
 
<h2>1. What is a Liquid Fluoride Thorium Reactor (LFTR)?</h2><p>A LFTR is a type of nuclear reactor that uses liquid fluoride salts as both its fuel and coolant. It differs from traditional nuclear reactors which use solid fuel and water as a coolant.</p><h2>2. How is a LFTR different from other nuclear reactors?</h2><p>LFTRs use thorium as their primary fuel source, which is more abundant and less radioactive than uranium used in traditional reactors. They also operate at atmospheric pressure, making them inherently safer and more efficient.</p><h2>3. What are the advantages of using a LFTR?</h2><p>There are several advantages of LFTRs, including their ability to produce less nuclear waste, their inherent safety due to their design, and their potential to use thorium as a more abundant and less expensive fuel source.</p><h2>4. Are there any potential drawbacks to using LFTRs?</h2><p>One potential drawback is the lack of existing infrastructure and technology for LFTRs, as they are still in the research and development phase. Additionally, there may be concerns about the disposal of the radioactive waste produced by LFTRs.</p><h2>5. Is LFTR technology currently being used?</h2><p>While there are no commercial LFTRs currently in operation, there have been several successful test reactors built and operated in the past. Research and development on LFTR technology is ongoing, with many countries and companies investing in its potential as a future energy source.</p>

1. What is a Liquid Fluoride Thorium Reactor (LFTR)?

A LFTR is a type of nuclear reactor that uses liquid fluoride salts as both its fuel and coolant. It differs from traditional nuclear reactors which use solid fuel and water as a coolant.

2. How is a LFTR different from other nuclear reactors?

LFTRs use thorium as their primary fuel source, which is more abundant and less radioactive than uranium used in traditional reactors. They also operate at atmospheric pressure, making them inherently safer and more efficient.

3. What are the advantages of using a LFTR?

There are several advantages of LFTRs, including their ability to produce less nuclear waste, their inherent safety due to their design, and their potential to use thorium as a more abundant and less expensive fuel source.

4. Are there any potential drawbacks to using LFTRs?

One potential drawback is the lack of existing infrastructure and technology for LFTRs, as they are still in the research and development phase. Additionally, there may be concerns about the disposal of the radioactive waste produced by LFTRs.

5. Is LFTR technology currently being used?

While there are no commercial LFTRs currently in operation, there have been several successful test reactors built and operated in the past. Research and development on LFTR technology is ongoing, with many countries and companies investing in its potential as a future energy source.

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