The forum discussion centers on the allocation of funding for fusion power development, highlighting the misconceptions surrounding its potential as an infinite, clean energy source. Participants emphasize that while fusion has significant long-term potential, current technology does not yet produce more energy than it consumes. The ITER project, with a projected cost of $14 billion over 30 years, exemplifies the high financial commitment required for fusion research. Concerns are raised about the environmental impact and safety of fusion, particularly regarding the exotic particles produced during reactions and the challenges of reactor shielding.
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James Leighe said:Why the hell don't we put more money into this?
mcjosep said:maybe because it doesn't produce more power than it uses yet.
DR13 said:I can't tell if this is a joke? You do realize that outputting more energy than is inputted breaks the laws of physics...
James Leighe said:infinite free clean energy
From WIKI (Yes, I know, if you want better sources I can certainly oblige): "Assuming a fusion energy output equal to the 1995 global power output of about 100 EJ/yr (= 1 x 1020 J/yr) and that this does not increase in the future, then the known current lithium reserves would last 3000 years, lithium from sea water would last 60 million years, and a more complicated fusion process using only deuterium from sea water would have fuel for 150 billion years."fatra2 said:From the knowhow we have gained in the past few years, we can estimate that we would have fuel (on Earth) for nuclear fusion for the next few hundred years.
People would be more likely to fund if it they saw the government take the lead. It's never even mentioned, we are instead funding corn power, wind power, possibly more nuclear power (which is cool with me), light power and other things like that that we all know can't output enough power to do it alone (except of course nuclear power, but we only have fuel for a few hundred years for that).gmax137 said:what's stopping you from putting all of your money into it? I know that sounds pissy, but I mean really, can you answer that question?
A considerable amount is very subjective. Just a tiny pinch of the money from the war in Iraq and Afghanistan and we could all be flying around in space cars because we have so much energy from fusion.Fusion power is not infinite, free, or completely clean but we do already put a considerable amount into researching it.
Have you looked for information on fusion funding? It's out there. Google it. And recognize, there is a difference between funding fission and fusion. Fusion funding is for research and fission funding funds actual power plants.James Leighe said:People would be more likely to fund if it they saw the government take the lead. It's never even mentioned, we are instead funding corn power, wind power, possibly more nuclear power (which is cool with me), light power and other things like that that we all know can't output enough power to do it alone (except of course nuclear power, but we only have fuel for a few hundred years for that).
That's absurd.A considerable amount is very subjective. Just a tiny pinch of the money from the war in Iraq and Afghanistan and we could all be flying around in space cars because we have so much energy from fusion.
It isn't too bad, but understand that the reactor would turn itself and anything around it inside its containment system radioactive....strictly clean (but pure deuterium plants would be extremely clean I imagine)
You still need to turn that water into nuclear fuel - its not like you can just pump it out of the ocean and into the power plant. And you still need to build the power plant!and strictly free (we only need water for deuterium plants)...
Maybe, but only maybe: we don't even know if it is "possible" yet!but it's better than anything else possible right?
Extracting one chemical from another requires energy - there is no way around the first law of thermo. And construction cost is never forgotten in a good economic analysis. Fusion plants will no doubt be extremely expensive.I'm assuming we would find methods to extract lithium with no trouble from the sea and in time the initial cost of research/construction will be forgotten and power will be flowing pretty hard.
What's reasonable? It's already in the hundreds of millions of dollars a year. Here's a single international project that is funded for a projected cost of $14 billion over 30 years, or $450 million a year (probably front-end loaded for construction). http://en.wikipedia.org/wiki/ITEROr, where have I gone wrong? Is the greatest source of ridiculous energy sitting right in front of us but no-one wants to put a reasonable effort?
For D+T fusion? With the available deuterium, a few hundred years is many orders of magnitude too low assuming today's energy load. Are you assuming some extraordinary increase in load?fatra2 said:Not so.
From the knowhow we have gained in the past few years, we can estimate that we would have fuel (on Earth) for nuclear fusion for the next few hundred years.
There are difficult neutron activation and tritium handling issues, but this makes no sense. Other than neutrons and alphas, to what 'many' and 'very exotic' particles are you referring? What D+T fusion reaction or side reaction makes TeV particles? The interactions of neutrons with materials is well documented.[...]The idea of clean is also relative. At this temperature, the particles collision and produce an outstanding amount of energy, but not only in its purest form. There are many particles, very exotic, created from reactions like these, that carry energy of many MeV, which it might even reach the TeV in some case. No one knows how these particles would react with the sheilding environment.
mheslep said:There are difficult neutron activation and tritium handling issues, but this makes no sense. Other than neutrons and alphas, to what 'many' and 'very exotic' particles are you referring? What D+T fusion reaction or side reaction makes TeV particles? The interactions of neutrons with materials is well documented.
fatra2 said:Hi there,
Were you ever in an environment of more than 100 million degrees? If not, I can tell you that no one has. Therefore, it is difficult to know what type of particles will be created from such fusion.
Theory tells us many things, but without any experimental facts, it is hard to know precisely what will be the end result of such fusion.
Secondly, by clean I understand that it has no or very little radioactivity (that could be dangerous to humans). With such high energy particles, how will the sheilding resist over the years. It is also quite known that the danger of fission power plant does not only reside in the fission products, but also in the residual shielding materials, that has to be dismantled at the end. This is where the workers from a NPP get a lot and a lot of radiation exposure. To come back to the fusion, how do you know that the shielding material will not react in a very ackward way when exposed to this type of super high energy particle flux?
Cheers
mheslep said:Yep, but that assumes away the safety and proliferation issues with fission.