/*! This file is auto-generated */ .wp-block-button__link{color:#fff;background-color:#32373c;border-radius:9999px;box-shadow:none;text-decoration:none;padding:calc(.667em + 2px) calc(1.333em + 2px);font-size:1.125em}.wp-block-file__button{background:#32373c;color:#fff;text-decoration:none} Problem 26 Radioactive copper-64 decays wit... [FREE SOLUTION] | 91Ó°ÊÓ

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Chapter 19: Problem 26

Radioactive copper-64 decays with a half-life of \(12.8\) days. a. What is the value of \(k\) in \(\mathrm{s}^{-1}\) ? b. A sample contains \(28.0 \mathrm{mg}^{64} \mathrm{Cu}\). How many decay events will be produced in the first second? Assume the atomic mass of \({ }^{64} \mathrm{Cu}\) is \(64.0 .\) c. A chemist obtains a fresh sample of \({ }^{64} \mathrm{Cu}\) and measures its radioactivity. She then determines that to do an experiment, the radioactivity cannot fall below \(25 \%\) of the initial measured value. How long does she have to do the experiment?

Short Answer

Expert verified
a. The decay constant, \(k = 6.265 \times 10^{-7} \, \mathrm{s}^{-1}\). b. The number of decay events in the first second of a 28.0 mg sample of copper-64 is \(1.66 \times 10^{15}\, decay \, events\). c. The chemist has 30.5 days to do the experiment before the radioactivity falls below 25% of the initial value.

Step by step solution

01

Calculate the decay constant

We need to find the decay constant, k in s^-1. We can use the formula for half-life: \(t_{1/2} = \frac{ln(2)}{k}\), where \(t_{1/2}\) is the half-life of the element. Rearrange the formula to get: \(k = \frac{ln(2)}{t_{1/2}} \) First, we will need to convert half-life '12.8 days' to seconds: \(12.8 \,days \times 24 \,hours/day \times 60 \,minutes/hour \times 60 \,s/minute = 1105920 \,s\) Now, plug in the value of \(t_{1/2}\) into the formula: \(k = \frac{ln(2)}{1105920\,s} = 6.265 \times 10^{-7} \,\mathrm{s}^{-1}\)
02

Calculate the number of decay events in the first second

We have a sample of 28.0 mg of copper-64, and its atomic mass is 64.0. First, we need to find the number of atoms, N, from the given mass: Formula: \( N =\frac{mass}{atomic \,mass} \times N_A\), where \(N_A\) is Avogadro's number, \(6.022 \times 10^{23}\,atoms/mol\). Plug in the values for the given mass and atomic mass of copper-64: \(N =\frac{28.0 \,\mathrm{mg}}{64.0 \,g/mol} \times 6.022 \times 10^{23} \,atoms/mol\) \(N = 2.65 \times 10^{21} \,atoms\) Now we can use the decay constant, k, and the number of atoms, N, to find the number of decay events in the first second. The decay rate, R, at any given time is given by the formula: \(R(t) = -\frac{dN(t)}{dt} = kN(t)\) We are asked for the decay rate at the first second, so t = 1 second. At t = 0 seconds, N(t) = N (the initial number of atoms). Then, R(1 s) = kN: \(R(1\, s) = 6.265 \times 10^{-7}\, \mathrm{s}^{-1} \times 2.65 \times 10^{21} \,atoms = 1.66 \times 10^{15} \,decay \,events\)
03

Calculate the time available for the experiment

To find the time available for the experiment, we need to solve the radioactive decay formula \(N(t) = N(0)e^{-kt}\) for t, given that N(t) cannot fall below 25% of N(0). Let's set N(t) = 0.25N(0) and solve for t: \(0.25N(0) = N(0)e^{-kt}\) Divide both sides by \(N(0)\): \(0.25 = e^{-kt}\) Now, take the natural logarithm of both sides: \(ln(0.25) = -kt\) Finally, solve for t: \(t = -\frac{ln(0.25)}{k} = \frac{ln(4)}{6.265 \times 10^{-7} \, \mathrm{s}^{-1}} = 2.638 \times 10^6 \,s\) Now let's convert the seconds to days: \(2.638 \times 10^6\,s \times \frac{1\,min}{60\,s} \times \frac{1\,hour}{60\,min} \times \frac{1\,day}{24\,hours} = 30.5\,days\) The chemist has 30.5 days to do the experiment before the radioactivity falls below 25% of the initial value.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Half-life
Half-life is a term used to describe the time it takes for half of the radioactive atoms in a sample to decay. This concept is crucial in understanding radioactive decay because it allows scientists and researchers to predict how long a radioactive substance will remain active. A half-life is characteristic of each radioactive isotope and does not depend on the initial amount of the substance or its concentration. In simpler terms, if you have a sample of a radioactive element with a half-life of 5 years, after 5 years only half of the sample will remain; the other half will have transmuted into different atoms or energy. Half-life allows for the calculation of the decay constant, which is necessary for solving various nuclear chemistry problems.

When improving educational material on half-life, it's important to ensure that students can connect the concept to practical examples, such as medical imaging with radioactive tracers or carbon dating in archaeology, which helps in reinforcing the concept's real-world application.
Decay Constant
The decay constant, represented by the symbol \(k\), is a probability that quantifies the rate at which an atom of a radioactive substance decays per unit time. Mathematically, the decay constant is the inverse of the half-life multiplied by the natural logarithm of 2 (\(ln(2)\)). The formula \(k = \frac{ln(2)}{t_{1/2}}\) directly relates the decay constant to half-life, showing that a substance with a shorter half-life has a higher decay constant, indicating it is more radioactive and will decay faster.

To make the concept more understandable in educational content, it's useful to incorporate visual aids, like decay curves, that illustrate how the probability of decay changes over time. Additionally, providing step-by-step calculations, as seen in the original exercise, can help students grasp the process of determining the decay constant from a known half-life.
Nuclear Chemistry
Nuclear chemistry is the subfield of chemistry dealing with radioactivity, nuclear processes, and nuclear properties. It involves studying various types of radioactive decay, nuclear synthesis, and the chemical applications of radioisotopes. A common application of nuclear chemistry is in medicine, where isotopes are used for diagnosis and treatment in nuclear medicine. Another pivotal application is in the field of energy production through nuclear reactors. Understanding the basics of nuclear transformations, such as alpha decay, beta decay, and gamma radiation, is essential for those studying nuclear chemistry.

In educational content, explaining the interplay between mass, energy, and the stability of the nucleus aids in the comprehensive understanding of nuclear chemistry. Highlighting safety precautions and ethical considerations is also important due to the potential risks associated with radioactive materials. Introducing historical context, such as the development of the atomic theory and notable discoveries, can engage students and provide a broader perspective on the subject.

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Most popular questions from this chapter

The easiest fusion reaction to initiate is $${ }_{1}^{2} \mathrm{H}+{ }_{1}^{3} \mathrm{H} \longrightarrow{ }_{2}^{4} \mathrm{He}+{ }_{0}^{1} \mathrm{n}$$ Calculate the energy released per \({ }_{2}^{4} \mathrm{He}\) nucleus produced and per mole of \({ }_{2}^{4}\) He produced. The atomic masses are \({ }_{1}^{2} \mathrm{H}, 2.01410 ;{ }_{1}^{3} \mathrm{H}\), \(3.01605\); and \({ }_{2}^{4}\) He, \(4.00260\). The masses of the electron and neutron are \(5.4858 \times 10^{-4}\) amu and \(1.00866\) amu, respectively.

Iodine- 131 is used in the diagnosis and treatment of thyroid disease and has a half-life of \(8.0\) days. If a patient with thyroid disease consumes a sample of \(\mathrm{Na}^{131}\) I containing \(10 . \mu \mathrm{g}{ }^{131} \mathrm{I}\), how long will it take for the amount of \({ }^{131} \mathrm{I}\) to decrease to \(1 / 100\) of the original amount?

Write an equation describing the radioactive decay of each of the following nuclides. (The particle produced is shown in parentheses, except for electron capture, where an electron is a reactant.) a. \({ }^{68} \mathrm{Ga}\) (electron capture) c. \({ }^{212} \mathrm{Fr}(\alpha)\) b. \(^{62} \mathrm{Cu}\) (positron) d. \({ }^{129} \mathrm{Sb}(\beta)\)

The curie (Ci) is a commonly used unit for measuring nuclear radioactivity: 1 curie of radiation is equal to \(3.7 \times 10^{10}\) decay events per second (the number of decay events from \(1 \mathrm{~g}\) radium in \(1 \mathrm{~s}\) ). a. What mass of \(\mathrm{Na}_{2}{ }^{38} \mathrm{SO}_{4}\) has an activity of \(10.0 \mathrm{mCi}\) ? Sulfur38 has an atomic mass of \(38.0\) and a half-life of \(2.87 \mathrm{~h}\). b. How long does it take for \(99.99 \%\) of a sample of sulfur- 38 to decay?

One type of commercial smoke detector contains a minute amount of radioactive americium- \(241\left({ }^{241} \mathrm{Am}\right)\), which decays by \(\alpha\) -particle production. The \(\alpha\) particles ionize molecules in the air, allowing it to conduct an electric current. When smoke particles enter, the conductivity of the air is changed and the alarm buzzes. a. Write the equation for the decay of \({ }_{95}^{241} \mathrm{Am}\) by \(\alpha\) -particle production. b. The complete decay of \({ }^{241}\) Am involves successively \(\alpha, \alpha, \beta\), \(\alpha, \alpha, \beta, \alpha, \alpha, \alpha, \beta, \alpha\), and \(\beta\) production. What is the final stable nucleus produced in this decay series? c. Identify the 11 intermediate nuclides.
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