Difference between revisions of "Mo-99 Production"

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The above report suggests that
 
The above report suggests that
  
1.) you get about <math>10^{12} \frac{neutrons}{s kW}</math> when a 30 MeV electron beam hits a converter like Tungsten producing photons which hit a 5 cm thick Moly target.
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1.) you get about <math>10^{12} \frac{neutrons}{s \cdot kW}</math> when a 30 MeV electron beam hits a converter like Tungsten producing photons which hit a 5 cm thick Moly target. A 100 kW electron beam could make about 800 Ci/s of Mo-99.
  
2.) The <math>(\gamma, n)</math> X-sect peaks at 160 mbarns when the photon energy is 15 MeV
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2.) The <math>^{100}Mo(\gamma, f)</math> X-sect peaks at 160 mbarns when the photon energy is 15 MeV:(photofission of Mo-100 and U-238 have similar X-sections)
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3.) single neutron emissions makes up about 60% of the photofission X-section <math>\Rightarrow</math> <math>^{100}Mo(\gamma, n)</math> X-sect is about 96 mbarns when photon energy is 15 MeV
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4.) 40 million nuclear medicine procedures are performed each year, 20 million in the US.  80% of those procedures use Mo-99.
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5.) The U.S. uses 6,000 - 7,000 6-day curies per week.  6-day curies = amount of Mo-99 left after 6 days ( half life is 66 hours < 3 days). <math>\Rightarrow</math> 14,000 curies per week.
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Combining "1" and "5" means I need a 12 Watt dedicated electron machine to make Mo-99 each week for the U.S.?
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If my technique for making Mo-99 uses 10, 50 micron thick foils of Mo-100 instead of a 5 cm thick target, then I need a 1200 Watt electron accelerator.

Latest revision as of 02:04, 31 December 2010

TRIUMF task force report 2008

The above report suggests that

1.) you get about [math]10^{12} \frac{neutrons}{s \cdot kW}[/math] when a 30 MeV electron beam hits a converter like Tungsten producing photons which hit a 5 cm thick Moly target. A 100 kW electron beam could make about 800 Ci/s of Mo-99.

2.) The [math]^{100}Mo(\gamma, f)[/math] X-sect peaks at 160 mbarns when the photon energy is 15 MeV:(photofission of Mo-100 and U-238 have similar X-sections)

3.) single neutron emissions makes up about 60% of the photofission X-section [math]\Rightarrow[/math] [math]^{100}Mo(\gamma, n)[/math] X-sect is about 96 mbarns when photon energy is 15 MeV

4.) 40 million nuclear medicine procedures are performed each year, 20 million in the US. 80% of those procedures use Mo-99.

5.) The U.S. uses 6,000 - 7,000 6-day curies per week. 6-day curies = amount of Mo-99 left after 6 days ( half life is 66 hours < 3 days). [math]\Rightarrow[/math] 14,000 curies per week.


Combining "1" and "5" means I need a 12 Watt dedicated electron machine to make Mo-99 each week for the U.S.?

If my technique for making Mo-99 uses 10, 50 micron thick foils of Mo-100 instead of a 5 cm thick target, then I need a 1200 Watt electron accelerator.