Difference between revisions of "Solutions 2"
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#1000g Th(NO3)4 = 2.083 mol arrow N(Th)= 1.25<math>\cdot</math>10<sup>24</sup> atoms. This is natural thorium, where the equilibrium in Th-series will lead to equal aktivity of <sup>232</sup>Th and <sup>228</sup>Th. Since <sup>232</sup>Th has a incredibly long half-life and <sup>228</sup>Th is short compared to this and we can approximate N(Th)<math>\approx</math>N(<sup>232</sup>Th)=1.25<math>\cdot</math>10^24 The disintegration for both is 1.96<math>\cdot</math>10<sup>6</sup>Bq. | #1000g Th(NO3)4 = 2.083 mol arrow N(Th)= 1.25<math>\cdot</math>10<sup>24</sup> atoms. This is natural thorium, where the equilibrium in Th-series will lead to equal aktivity of <sup>232</sup>Th and <sup>228</sup>Th. Since <sup>232</sup>Th has a incredibly long half-life and <sup>228</sup>Th is short compared to this and we can approximate N(Th)<math>\approx</math>N(<sup>232</sup>Th)=1.25<math>\cdot</math>10^24 The disintegration for both is 1.96<math>\cdot</math>10<sup>6</sup>Bq. | ||
#6.43<math>\cdot</math>10<sup>-8</sup>g | #6.43<math>\cdot</math>10<sup>-8</sup>g | ||
− | #10000 Bq <sup>228</sup>Ra = 2.62<math>\cdot</math>10<sup>12</sup> atoms = 90% arrow 100% 2.92<math>\cdot</math>10<sup>12</sup> atoms. If <sup>232</sup>Th is N1 and <sup>228</sup>Ra is N2 we can use the formulas for mother/daughter realations:<math>N_{2}=\frac{\lambda_{1}}{\lambda_{2}-\lambda_{1}}N_{1,0}(e^{-\lambda 1\cdot t}-e^{-\lambda 2\cdot t})</math> <math>N_{1,0}=N_{2}\frac{\lambda_{2}-\lambda_{1}}{\lambda_{1}}\cdot \frac{1}{e^{-\lambda 1\cdot t}-e^{-\lambda 2\cdot t}}</math> | + | #10000 Bq <sup>228</sup>Ra = 2.62<math>\cdot</math>10<sup>12</sup> atoms = 90% arrow 100% 2.92<math>\cdot</math>10<sup>12</sup> atoms. If <sup>232</sup>Th is N1 and <sup>228</sup>Ra is N2 we can use the formulas for mother/daughter realations:<math>N_{2}=\frac{\lambda_{1}}{\lambda_{2}-\lambda_{1}}N_{1,0}(e^{-\lambda 1\cdot t}-e^{-\lambda 2\cdot t})</math> <math>N_{1,0}=N_{2}\frac{\lambda_{2}-\lambda_{1}}{\lambda_{1}}\cdot \frac{1}{e^{-\lambda 1\cdot t}-e^{-\lambda 2\cdot t}}=6.25\cdot10^{22}\, atoms</math><math>\frac{6.26\cdot 10^{22}}{6.022\cdot 10^{23}}=0.104 \, mol\cdot480.06 \, g/mol=50 \, g Th(NO_{3})_{4}</math> |
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Revision as of 09:08, 19 June 2012
1:
- 1000g Th(NO3)4 = 2.083 mol arrow N(Th)= 1.25 1024 atoms. This is natural thorium, where the equilibrium in Th-series will lead to equal aktivity of 232Th and 228Th. Since 232Th has a incredibly long half-life and 228Th is short compared to this and we can approximate N(Th) N(232Th)=1.25 10^24 The disintegration for both is 1.96 106Bq.
- 6.43 10-8g
- 10000 Bq 228Ra = 2.62 1012 atoms = 90% arrow 100% 2.92 1012 atoms. If 232Th is N1 and 228Ra is N2 we can use the formulas for mother/daughter realations: