Difference between revisions of "Radioactive Disintegration (Introduction to Radiochemistry)"

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<br> <math>N_{2} = \frac{\lambda_{1}}{\lambda_{2}}N_{0}e^{-\lambda_{1}}</math>  
 
<br> <math>N_{2} = \frac{\lambda_{1}}{\lambda_{2}}N_{0}e^{-\lambda_{1}}</math>  
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   \end{matrix}   
 
   \end{matrix}   
 
  </math>
 
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when&nbsp;<math>e^{-\lambda_{2}t} +rightarrow o</math> the equation above is called a secular radioactive equilibrium and can be written as the following:
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<math>\lambda_{2} N_{2} = \lambda_{1} N_{1}</math>

Revision as of 14:59, 2 July 2012

Radioactive disintegration is a stochastic proces, which means a random process, that can be described statistically. In this task you will learn about the secular radioactive equilibrium, and how any measure of a radioactive source is stated with uncertainty.

In a sample with N radioactive atoms of a particular nuclide, the number of atoms that disintegrates with the time dt will be proportional with N, see the formula below.

[math]-\frac{dN}{dt} = \lambda N \rightarrow \lambda N = A[/math],

where λ is the disintegration constant and A is the rate of disintegration.

The above equation can be solved into the following:

Nt = N0e - λt

N0 is the number of atoms of the nuclide at hand present at t = 0. The time past when half of the nuclides has disintegrated is called the half-life.

N = N0/2 can be placed into equation 1.1 to give the following connection between the disintegration constant and the half-life:

[math]\lambda = \frac{ln2}{T_{1/2}}[/math]

The half-life is a characteristic value for each radioactive nuclide. A radioactive nuclide will often disintegrate into a product that is radioactive as well: Nucleus 1[math]\rightarrow[/math]Nucleus 2 [math]\rightarrow[/math]Nucleus 3. The initial nucleus is usually referred to as the mother nuclide and the product as the daughter nuclide.

Assume that at the time t = 0, N0 of the mother is N1(t =0), N2(t=0) and N3(t=0), the change in number of mother- and daughter nuclides can then respectively be described through the following equations:

dN1 = -λN1dt

dN2λ1N1dt - λ2N2dt


[math]N_{2} = \frac{\lambda_{1}}{\lambda_{2} -\lambda_{1}} N_{0} (e^{-\lambda_{1} t} -e^{-\lambda_{2}t}) \rightarrow N_{2} = \frac{\lambda_{1}}{\lambda_{2} -\lambda_{1}} N_{1}(t) ( 1 - e^{-(\lambda_{2} - \lambda_{1}t)})[/math]

If the half-life of the mother is much less than that of the daughter, equation 1.2 can be simplified into:


[math]N_{2} = \frac{\lambda_{1}}{\lambda_{2}} N_{0} (e^{-\lambda_{1} t} -e^{-\lambda_{2}t}) \rightarrow N_{2} \frac{\lambda_{1}}{\lambda_{2}}N_{1}(t) (1-e^{-\lambda_{2}t}) [/math]


where [math](1-e^{-\lambda_{2}t})[/math]is the saturation factor and [math]\lambda_{2}- \lambda_{1}\cong \lambda_{2}[/math]

The above equation can be further reduced by the assuption that t >> T1/2(2) (the observed time is much larger than the daughters half-life).


[math]N_{2} = \frac{\lambda_{1}}{\lambda_{2}}N_{0}e^{-\lambda_{1}}[/math]




[math] \begin{matrix}& N_{2} = \frac{\lambda_{1}}{\lambda_{2}} & \underbrace{N_{0}e^{-\lambda_{1}}} \\ & & N_{1} \end{matrix} [/math]

when [math]e^{-\lambda_{2}t} +rightarrow o[/math] the equation above is called a secular radioactive equilibrium and can be written as the following:

[math]\lambda_{2} N_{2} = \lambda_{1} N_{1}[/math]