Difference between revisions of "Solutions 7"

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It is in total 3.58 mol = 2.1562<math>\cdot</math> 10<sup>24</sup> atoms of potassium in a average human where 12% that is 2.5876 <math>\cdot</math> 10<sup>20</sup> is <sup>40</sup>K
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# It is in total 3.58 mol = 2.1562<math>\cdot</math> 10<sup>24</sup> atoms of potassium in a average human where 12% that is 2.5876<math>\cdot</math>10<sup>20</sup> is <sup>40</sup>K <br> <math>T_{(1/2)}=1.28\cdot10^{9}=4.0283 \cdot 10^{16}\,s</math><br> <math>\lambda= \frac{\ln 2}{T_{(1/2)}} = \frac{ln2}{4.0283\cdot 10^{16}}=1.7206\cdot 10^{-17}\, s^{-1}</math><br> <math>D=\lambda \cdot N= 2.5876\cdot10^{20}\cdot 1.7206\cdot 10^{-17} s^{-1}=4452.45\, Bq</math>
<math>T(1/2)=1.28\cdot10^{9}=4.0283 10^{16}\,s</math>
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# First calculate the dose per second:<br> <math>4452.45\, Bq \cdot 400\,  keV Bq^{-1} = 1.78\cdot 10^{6} keV s^-1</math><br> Then calculate it to joule per second:<br> <math>1.602\cdot 10^{-16}\, J/keV \cdot 1.78\cdot 10^{6}\, keV/s = 2.8534\cdot 10^{-10}\,  J/s</math><br> which gives: <br> <math>2.8534\, J/s \cdot\frac{10^{-10}}{70\, kg} = 4.076\cdot 10^{-12} J/(kg s)</math><br> As the  dose can be assumed to be constant trough a human life for each year we will recive a dose of:<br><math>3.145\cdot 10^7 \, \frac{s}{year} \cdot 4.076\cdot 10^{-12}\, \frac{J}{kg\, s} = 1.28 10^-4\, \frac{Gy}{year} = 0.13\, \frac{mGy}{year}</math>
<math>\lambda= \frac{\ln 2}/{T_{(1/2)}} = \frac{ln2}/{4.0283 10^16}=1.7206\cdot 10^{-17} s^{-1}</math>
 
<math>D=\lambda \cdot N= 2.5876\cdot10^{20}\cdot 1.7206\cdot 10^{-17} s^{-1}=4452.45\, Bq</math>
 

Revision as of 12:09, 22 June 2012

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1:

  1. It is in total 3.58 mol = 2.1562[math]\cdot[/math] 1024 atoms of potassium in a average human where 12% that is 2.5876[math]\cdot[/math]1020 is 40K
    [math]T_{(1/2)}=1.28\cdot10^{9}=4.0283 \cdot 10^{16}\,s[/math]
    [math]\lambda= \frac{\ln 2}{T_{(1/2)}} = \frac{ln2}{4.0283\cdot 10^{16}}=1.7206\cdot 10^{-17}\, s^{-1}[/math]
    [math]D=\lambda \cdot N= 2.5876\cdot10^{20}\cdot 1.7206\cdot 10^{-17} s^{-1}=4452.45\, Bq[/math]
  2. First calculate the dose per second:
    [math]4452.45\, Bq \cdot 400\, keV Bq^{-1} = 1.78\cdot 10^{6} keV s^-1[/math]
    Then calculate it to joule per second:
    [math]1.602\cdot 10^{-16}\, J/keV \cdot 1.78\cdot 10^{6}\, keV/s = 2.8534\cdot 10^{-10}\, J/s[/math]
    which gives:
    [math]2.8534\, J/s \cdot\frac{10^{-10}}{70\, kg} = 4.076\cdot 10^{-12} J/(kg s)[/math]
    As the dose can be assumed to be constant trough a human life for each year we will recive a dose of:
    [math]3.145\cdot 10^7 \, \frac{s}{year} \cdot 4.076\cdot 10^{-12}\, \frac{J}{kg\, s} = 1.28 10^-4\, \frac{Gy}{year} = 0.13\, \frac{mGy}{year}[/math]
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