Could an RGA be used to detect fusion?
For example, if I attach an RGA onto my vacuum chamber doing D-D fusion, would it be able to detect the He3 and tritium produced? I'm thinking it won't, due to the very small amount produced, >100000 fusions/sec.
How could this be done?
Using an RGA to detect fusion
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- Nick Peskosky
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Re: Using an RGA to detect fusion
In theory yes it might be possible but the gear required is probably scant available to the amateur Fusioneer. Open Ion Source (OIS) RGAs that couple a quadropole element with an electron multiplier are the most common devices on the market. Unfortunately, the minimum operating pressure required for the ion sources in these analyzers is usually <10^-4Torr (well below the standard operating pressure of a Fusor). At pressures higher than this the higher mass constituent gasses will adsorb to and sputter the Ti/Mo/Pd/Au electrodes that comprise elements of the ion source and quadropole. Closed Ion Source (CIS) RGAs can sample in the 10^-2-10^-3Torr range but come with a hefty price tag. It might be possible to sample the gas stream entering the throat of a turbo/diffusion pump but it would require a very complex differential pumping design (ion pump/Ti sublimation pump on the RGA arm) and I doubt the He/Tritium markers would even present as parts-per-trillion (PPT) in the 'dirty' atmosphere of a typical home-brew Fusor. A lab grade all-Conflat system with ultrapure D2 and ultrapure flushing gasses might fit the bill. The chamber would need to be evacuated to <10-7Torr ranges (days of pumping/heating) just to get all of the 'krud' out of the gas stream prior to sampling. Even this would be a longshot once the plasma is ignited in the millitorr range.
Unless you have access to a local physics lab or semiconductor cleanroom (mass spec or leak detector) chances are you'll need a rather deep wallet to buy the required RGA/connectors/processors/software required for a complete setup.
Unless you have access to a local physics lab or semiconductor cleanroom (mass spec or leak detector) chances are you'll need a rather deep wallet to buy the required RGA/connectors/processors/software required for a complete setup.
Nick Peskosky
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"The whole of science is nothing more than the refinement of everyday thinking." - Albert Einstein
NPeskosky@gmail.com
"The whole of science is nothing more than the refinement of everyday thinking." - Albert Einstein
Re: Using an RGA to detect fusion
The amount of tritium produced is so small that it would be unlikely to be dectectable by an RGA, not to mention that it would be obscured by the H-D ion.
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Re: Using an RGA to detect fusion
Doug Coulter has done it on his system and has detected T. You you need a pressure reducing valve and separate pump to sample the chamber since the chamber runs at a much higher pressure than the RGA can handle, the RGA needs to be at least in the -4 range, preferably better.
RGAs are all over ebay, you can find Inficon transpectors all the time. I picked up another Dycor Dymaxion 200M (200AMU with MCP) for less than $200 if I remember. Stuck it on my SEM to check it out and it works fine.
RGAs are all over ebay, you can find Inficon transpectors all the time. I picked up another Dycor Dymaxion 200M (200AMU with MCP) for less than $200 if I remember. Stuck it on my SEM to check it out and it works fine.
Re: Using an RGA to detect fusion
Did Doug post data on this finding? The usual RGA can't resolve T from HD.
- Richard Hull
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Re: Using an RGA to detect fusion
Stock RGA's will not detect T in an average amateur fusor which never reaches 250,000 T/sec. However, a properly operated and reduced pressure RGA fitted with an additional, optional, electron multiplier and a fusor operating far in excess of 2 million T/sec, might, just might, see T.
Based on the gas pressure and number of gas molecules in an operating fusor, the T produced is such a tiny fraction of the whole that the average RGA stands no chance of detection. We have done all the calculations in past posts here.
The average yahoo with an average fusor and the finest RGA available will never see T.
Richard Hull
Based on the gas pressure and number of gas molecules in an operating fusor, the T produced is such a tiny fraction of the whole that the average RGA stands no chance of detection. We have done all the calculations in past posts here.
The average yahoo with an average fusor and the finest RGA available will never see T.
Richard Hull
Progress may have been a good thing once, but it just went on too long. - Yogi Berra
Fusion is the energy of the future....and it always will be
The more complex the idea put forward by the poor amateur, the more likely it will never see embodiment
Fusion is the energy of the future....and it always will be
The more complex the idea put forward by the poor amateur, the more likely it will never see embodiment
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Re: Using an RGA to detect fusion
What about He3? Since helium is noble, would a stock RGA detect its accumulation in the chamber?
Re: Using an RGA to detect fusion
He3 is detectable with an RGA but suffers the same problem as detecting tritium in the presence of a large background of deuterium and water, which will produce a mass 3 HD molecular ion (unresolvable from T and He3 by the usual RGA analyzer). Detecting the TT molecular ion (mass 6) would be statistically highly improbable given the extremely low level of tritium compared to the high background pressure of deuterium in a fusor. The best chance of seeing tritium in a fusor would likely be as the DT molecular ion at mass 5 where there would be fewer interferences.
Another problem with quadrupole RGA's not mentioned here so far is the so called "zero blast" where neutrals going straight through the analyzer obscure the low mass region. MKS/Granville Phillips touts their ion trap-based Vacuum Quality Monitor as the solution to this problem for observing the low mass ions. The best shot at observing tritium as a fusion product could be by observing DT with the VQM. Unfortunately, the VQM is a relatively new product, and there are few of them on the surplus market as yet.
To summarize, tritium detection by mass spectrometry is not normally used as a diagnostic for fusion even in big time experiments. Ian Hutchinson, author of the definitive text on plasma diagnostics in fusion research, doesn't even mention it
Another problem with quadrupole RGA's not mentioned here so far is the so called "zero blast" where neutrals going straight through the analyzer obscure the low mass region. MKS/Granville Phillips touts their ion trap-based Vacuum Quality Monitor as the solution to this problem for observing the low mass ions. The best shot at observing tritium as a fusion product could be by observing DT with the VQM. Unfortunately, the VQM is a relatively new product, and there are few of them on the surplus market as yet.
To summarize, tritium detection by mass spectrometry is not normally used as a diagnostic for fusion even in big time experiments. Ian Hutchinson, author of the definitive text on plasma diagnostics in fusion research, doesn't even mention it