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Chapter 2: Problem 42

The mass of a carbon-12 atom is taken to be exactly 12 u. Are there likely to be any other atoms with an exact integral (whole number) mass, expressed in u? Explain.

Short Answer

Expert verified
Although the atomic mass of a carbon-12 atom is defined as exactly 12u, there are no other atoms with an exact whole-number atomic mass when expressed in u. This is because atomic mass is a weighted average of the masses of an element's different isotopes, and the masses of protons and neutrons are not exactly 1u each. Therefore, atomic mass expressed in u would not be exactly integral, apart from carbon-12.

Step by step solution

01

Understanding Atomic Mass Units

To understand the problem, first it is necessary to know what an atomic mass unit is. It is a unit of mass used to express atomic and molecular weights, where the carbon-12 atom is taken as the standard and assigned a value of 12u. This means 1u is 1/12 of the mass of a carbon-12 atom.
02

Clarifying Exact Integral Atomic Mass

The atomic mass of any atom, expressed in u, is not an exact integer number (except for carbon-12), due to the presence of various isotopes with different numbers of neutrons, and the fact that the mass of a neutron and a proton are not exactly 1u. Therefore, the atomic mass of an element is a weighted average of the masses of all the naturally occurring isotopes. Thus, atomic masses are usually not whole numbers.
03

Reason for Non-Integral Atomic Mass

To understand why atomic masses are not usually exact integers, we must remember that an atom's total mass is contributed by protons, neutrons, and electrons. While the masses of protons and neutrons are each roughly 1u, they are not exactly 1u. Moreover, electrons also contribute, albeit a far smaller amount, to the total atomic mass. What's more, every element has various isotopes, which means that the atomic mass is indeed a weighted average of the isotopes. These factors result in atomic masses that are not exact integers.

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Key Concepts

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

Atomic Mass Unit
In the world of chemistry and physics, an atomic mass unit (abbreviated as u or amu) is a fundamental concept. It's a unit of mass that's extremely small, as it is used for measuring the mass of atoms and molecules. The beauty of the atomic mass unit lies in its precise definition, which is based on the mass of carbon-12.

To break it down:
  • 1 atomic mass unit is defined as one-twelfth (1/12) of the mass of a single carbon-12 atom.
  • Using this standard, it gives scientists a consistent way to compare the masses of different atoms and molecules.
  • It essentially allows us to express atomic and molecular weights in manageable numbers, rather than incredibly tiny figures.
Since the mass of a carbon-12 atom is defined to be exactly 12 u, this creates a benchmark for other atoms. However, it's important to note that atomic masses of most atoms are not perfect integers, unlike carbon-12.
Carbon-12
Carbon-12 is a standout isotope in the study of atomic mass. But why exactly?

Carbon is an element with several isotopes, but carbon-12 is special because it serves as the standard for the atomic mass unit. Its nucleus contains 6 protons and 6 neutrons, which sums up to 12 units of mass.

Here's why it's important:
  • Carbon-12 is chosen as the reference because it is abundant and stable.
  • It provides a reliable and reproducible standard for comparisons and calculations in chemistry.
  • This isotope is globally recognized, meaning measurements remain consistent across various scientific fields.
By setting carbon-12's mass at an exact 12 units, scientists can express the mass of other atoms in relation to it, giving rise to atomic mass units.
Isotopes
Isotopes add an intriguing layer of complexity to understanding atomic mass. Isotopes are different forms of the same element, each with the same number of protons but differing numbers of neutrons.

For example, carbon-12 and carbon-14 are both isotopes of carbon but have different masses due to their neutron count.

A few crucial points about isotopes:
  • Each isotope of an element contributes to its total atomic mass, depending on its abundance in nature.
  • The atomic mass of an element is essentially a weighted average reflecting these isotope contributions.
  • This means that the atomic mass is rarely a simple whole number, as it isn't just the count of protons and neutrons but also how frequently each isotope appears in nature.
The concept of isotopes is key to understanding why atomic masses are generally not whole numbers. It's the diverse neutron arrangements and their natural abundances that lead to varying atomic weights.

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Most popular questions from this chapter

How many atoms are present in a \(1.00 \mathrm{m}\) length of 20-gauge copper wire? A 20-gauge wire has a diameter of 0.03196 in., and the density of copper is \(8.92 \mathrm{g} / \mathrm{cm}^{3}\)

A 0.406 g sample of magnesium reacts with oxygen, producing \(0.674 \mathrm{g}\) of magnesium oxide as the only product. What mass of oxygen was consumed in the reaction?

In one experiment, the reaction of \(1.00 \mathrm{g}\) mercury and an excess of sulfur yielded \(1.16 \mathrm{g}\) of a sulfide of mercury as the sole product. In a second experiment, the same sulfide was produced in the reaction of \(1.50 \mathrm{g}\) mercury and \(1.00 \mathrm{g}\) sulfur. (a) What mass of the sulfide of mercury was produced in the second experiment? (b) What mass of which element (mercury or sulfur) remained unreacted in the second experiment?

Determine the only possible isotope (E) for which the following conditions are met: \(\bullet\)The mass number of \(\mathrm{E}\) is 2.50 times its atomic number. \(\bullet\)The atomic number of \(\mathrm{E}\) is equal to the mass number of another isotope (Y). In turn, isotope Y has a neutron number that is 1.33 times the atomic number of \(Y\) and equal to the neutron number of selenium- 82 .

The German chemist Fritz Haber proposed paying off the reparations imposed against Germany after World War I by extracting gold from seawater. Given that (1) the amount of the reparations was \(\$ 28.8\) billion dollars, (2) the value of gold at the time was about \(\$ 21.25\) per troy ounce ( \(1 \text { troy ounce }=31.103 \mathrm{g}),\) and (3) gold occurs in seawater to the extent of \(4.67 \times 10^{17}\) atoms per ton of seawater \((1 \text { ton }=2000\) lb), how many cubic kilometers of seawater would have had to be processed to obtain the required amount of gold? Assume that the density of seawater is \(1.03 \mathrm{g} / \mathrm{cm}^{3}\) (Haber's scheme proved to be commercially infeasible, and the reparations were never fully paid.)
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