Problem 67 $_{52}^{106} \mathrm{Te}$ is r... [FREE SOLUTION]

Chapter 29: Problem 67

$_{52}^{106} \mathrm{Te}$ is radioactive; it $\alpha$ decays to $^{102} \mathrm{s}_{0} \mathrm{Sn} .$ " $_{50}^{102} \mathrm{Sn}$ is itself radioactive and has a half-life of 4.5 s. At $t=0,$ a sample contains 4.00 mol of $^{106}$ Te and 1.50 mol of $^{102}$ so Sn. At $t=$ $25 \mu \mathrm{s},$ the sample contains $3.00 \mathrm{mol}$ of $^{106} \mathrm{Te}$ and $2.50 \mathrm{mol}$ of $^{102} \mathrm{s} 0$ Sn. How much 102 50 Sn will there be at $t=50 \mu \mathrm{s} ?$

Short Answer

Expert verified

Answer: Approximately 3.42 moles

Step by step solution

Find the decay constant of $_{50}^{102}\mathrm{Sn}$

Using the half-life formula, we can determine the decay constant $\lambda_{Sn}$ for $_{50}^{102}\mathrm{Sn}$: \[T_{1/2} = \frac{ln(2)}{\lambda}\] Given half-life $T_{1/2} = 4.5\mathrm{s}$, solve for $\lambda_{Sn}$: \[\lambda_{Sn} = \frac{ln(2)}{4.5}\] Now calculate $\lambda_{Sn}$: \[\lambda_{Sn} \approx 0.154\,\mathrm{s}^{-1}\]

Write the equation for moles of $_{50}^{102}\mathrm{Sn}$ and $_{52}^{106}\mathrm{Te}$

At time $t$, the equation for the moles of $_{50}^{102}\mathrm{Sn}$ is: \[n_{Sn}(t) = n_{Sn0}e^{-\lambda_{Sn}t}\] And the equation for moles of $_{52}^{106}\mathrm{Te}$ is: \[n_{Te}(t) = n_{Te0}e^{-\lambda_{Te}t}\] We are given 2 sets of values: 1. At $t = 0$: \[n_{Te0} = 4.00\,mol\] \[n_{Sn0} = 1.50\,mol\] 2. At $t = 25\,\mu s$: \[n_{Te}(25\,\mu s) = 3.00\,mol\] \[n_{Sn}(25\,\mu s) = 2.50\,mol\]

Find the decay constant of $_{52}^{106}\mathrm{Te}$

Use the given information to find $\lambda_{Te}$: \[3.00 = 4.00 e^{-\lambda_{Te}(25\,\mu s)}\] Solve for $\lambda_{Te}$: \[\lambda_{Te} = \frac{ln(4/3)}{25\,\mu s}\] Now calculate $\lambda_{Te}$: \[\lambda_{Te} \approx 1.849 \times 10^{-3}\,\mathrm{s}^{-1}\]

Calculate the amount of $_{50}^{102}\mathrm{Sn}$ at $t = 50\, \mu s$

To calculate the amount of $_{50}^{102}\mathrm{Sn}$ at $t = 50\, \mu s$, use the following equations: \[n_{Te}(50\,\mu s) = 4.00 e^{-\lambda_{Te}(50\,\mu s)}\] \[n_{Sn}(50\,\mu s) = \left[n_{Sn0} + \left(n_{Te0} - n_{Te}(50\,\mu s)\right)\right]e^{-\lambda_{Sn}(50\,\mu s)}\] First, calculate $n_{Te}(50\,\mu s)$: \[n_{Te}(50\,\mu s) \approx 2.08\,mol\] Now, calculate $n_{Sn}(50\,\mu s)$: \[n_{Sn}(50\,\mu s) = \left[1.50 + \left(4.00 - 2.08\right)\right]e^{-0.154 \times 50 \times 10^{-6}}\] Finally, calculate the value: \[n_{Sn}(50\,\mu s) \approx 3.42\,mol\] So, at $t = 50\, \mu s$, there will be approximately 3.42 moles of $_{50}^{102}\mathrm{Sn}$.

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Short Answer

Step by step solution

Find the decay constant of \(_{50}^{102}\mathrm{Sn}\)

Write the equation for moles of \(_{50}^{102}\mathrm{Sn}\) and \(_{52}^{106}\mathrm{Te}\)

Find the decay constant of \(_{52}^{106}\mathrm{Te}\)

Calculate the amount of \(_{50}^{102}\mathrm{Sn}\) at \(t = 50\, \mu s\)

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