Question:
Half-life of a radioactive substance is $20$ minute. The time between $20\%$ and $80\%$ decay will be :
Half-life of a radioactive substance is $20$ minute. The time between $20\%$ and $80\%$ decay will be :
Updated On: Jan 16, 2024
- 20 min
- 30 min
- 40 min
- 25 min
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The Correct Option is C
Solution and Explanation
Given that the half-life of a radioactive substance is $20\, min .$ So, $t_{1 / 2}=20\, min$.
For $20 \%$ decay, we have $80 \%$ of the substance left, hence
$\frac{80\, N_{0}}{100}=N_{0} e^{-\lambda t_{20}}\,\,\,...(i)$
where $N_{0}=$ initial undecayed substance and $t_{20}$ is the time taken for $20 \%$ decay.
For $80 \%$ decay, we have $20 \%$ of the substance left, hence
$\frac{20 N_{0}}{100}=N_{0} e^{-\lambda t_{80}}\,\,\,...(ii)$
Dividing E (i) and E (ii), we get
$4 =e^{\lambda\left(t_{80}-t_{20}\right)} $
$\Rightarrow \ln 4 =\lambda\left(t_{80}-t_{20}\right)$
(taking log on both sides)
$\Rightarrow 2 \ln 2=\frac{0.693}{t_{1 / 2}}\left(t_{80}-t_{20}\right)$
$\Rightarrow t_{80}-t_{20}=2 \times t_{1 / 2}=40\, min$
For $20 \%$ decay, we have $80 \%$ of the substance left, hence
$\frac{80\, N_{0}}{100}=N_{0} e^{-\lambda t_{20}}\,\,\,...(i)$
where $N_{0}=$ initial undecayed substance and $t_{20}$ is the time taken for $20 \%$ decay.
For $80 \%$ decay, we have $20 \%$ of the substance left, hence
$\frac{20 N_{0}}{100}=N_{0} e^{-\lambda t_{80}}\,\,\,...(ii)$
Dividing E (i) and E (ii), we get
$4 =e^{\lambda\left(t_{80}-t_{20}\right)} $
$\Rightarrow \ln 4 =\lambda\left(t_{80}-t_{20}\right)$
(taking log on both sides)
$\Rightarrow 2 \ln 2=\frac{0.693}{t_{1 / 2}}\left(t_{80}-t_{20}\right)$
$\Rightarrow t_{80}-t_{20}=2 \times t_{1 / 2}=40\, min$
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Following are the terms related to nucleus:
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