Solveeit Logo
Login

Question

Question: A radioactive nucleus with decay constant \(0.5{{s}^{-1}}\) is being produced at a constant rate of ...

A radioactive nucleus with decay constant 0.5s10.5{{s}^{-1}} is being produced at a constant rate of 100nuclei/s100nuclei/s. If at t=0t=0 there were no nuclei, the time when there are 5050 nuclei is
A)1s B)2ln(43) s C)ln2 s D)ln(43) s \begin{aligned} & A\text{)1s} \\\ & \text{B)2ln}\left( \dfrac{\text{4}}{\text{3}} \right)\text{ s} \\\ & \text{C)ln2 s} \\\ & \text{D)ln}\left( \dfrac{4}{3} \right)\text{ s} \\\ \end{aligned}

Explanation

Solution

From the radio-active decay law, rate of disintegration of a radioactive-nuclei at any instant is directly proportional to the number of radioactive nuclei present in the sample at that particular instant. An expression for radioactive decay is deduced from the given information by taking into consideration the production rate of nuclei in that element. To determine the time when there are 5050 nuclei, we make use of integration.
Formula used:
(dNdt)=λN\left( -\dfrac{dN}{dt} \right)=\lambda N

Complete answer:
We know that the rate of disintegration of a radioactive-nuclei at any instant is directly proportional to the number of radioactive nuclei present in the sample at that particular instant. Mathematically, rate of disintegration is given by
(dNdt)=λN\left( -\dfrac{dN}{dt} \right)=\lambda N
where
λ\lambda is the decay constant
NN is the number of nuclei present in the sample at a particular instant tt
dNdN is the number of disintegrated nuclei during a time interval dtdt
Let this be equation 1.
Coming to our question, we are provided that
λ=0.5s1\lambda =0.5{{s}^{-1}}
and that
dNdt+λN=100\dfrac{dN}{dt}+\lambda N=100
Let this be equation 2.
Rearranging equation 2, we have
dNdt+λN=100dNdt=100λNdN100λN=dt\dfrac{dN}{dt}+\lambda N=100\Rightarrow \dfrac{dN}{dt}=100-\lambda N\Rightarrow \dfrac{dN}{100-\lambda N}=dt
Now, integrating the above expression to determine tt, we have
050dN(100λN)=0tdt1λln(100λN)050=t1λln(100λ×50)+1λln(1000)=t\int\limits_{0}^{50}{\dfrac{dN}{\left( 100-\lambda N \right)}}=\int\limits_{0}^{t}{dt}\Rightarrow -\dfrac{1}{\lambda }\ln \left( 100-\lambda N \right)_{0}^{50}=t\Rightarrow -\dfrac{1}{\lambda }\ln \left( 100-\lambda \times 50 \right)+\dfrac{1}{\lambda }\ln \left( 100-0 \right)=t
Solving further by substituting the value of decay constant, we have
t=2×ln(10025)+2×ln(100)t=2×(ln100ln75)t=2×ln10075=2ln43st=-2\times \ln \left( 100-25 \right)+2\times \ln \left( 100 \right)\Rightarrow t=2\times \left( \ln 100-\ln 75 \right)\Rightarrow t=2\times \ln \dfrac{100}{75}=2\ln \dfrac{4}{3}s
Let this be equation 3.

Therefore, from equation 3, we can conclude that the correct answer is option BB.

Note:
Radioactivity refers to the phenomenon of spontaneous emission of radiation by the nucleus of a radio-active element. The three types of radiations, usually emitted by radioactive elements are alpha rays, beta rays and gamma rays. Students should take care in deducing equation 2. What is given in the question is the rate of production of nuclei, which is a consequence of both disintegration as well as generation. Hence deduced, is this equation.