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Chapter 7: Problem 41

(a) What is the general relationship between the size of an atom and its first ionization energy? (b) Which element in the periodic table has the largest ionization energy? Which has the smallest?

Short Answer

Expert verified
(a) The general relationship between atomic size and ionization energy is that as atomic size increases, ionization energy decreases, and as atomic size decreases, ionization energy increases. This is due to the varying attraction force between the nucleus and electrons. (b) Helium (He) has the largest ionization energy, while Francium (Fr) has the smallest ionization energy in the periodic table.

Step by step solution

01

Define ionization energy and atomic size

Ionization energy is the amount of energy required to remove an electron from a gaseous atom or ion. The general trend for ionization energy is that it increases from left to right across a period and decreases down a group in the periodic table. Atomic size is the distance between the nucleus of an atom and its outermost electrons. The general trend for atomic size is that it increases down a group and decreases from left to right across a period in the periodic table.
02

Relationship between atomic size and ionization energy

The general relationship between atomic size and ionization energy is that as atomic size increases, ionization energy decreases, and as atomic size decreases, ionization energy increases. This is because, as the atom becomes larger, electrons are further from the nucleus and experience a weaker attraction force from the nucleus. As a result, it's easier to remove an electron, and the ionization energy decreases. Conversely, as the atom becomes smaller, electrons are closer to the nucleus and experience a stronger attraction force from the nucleus, making it more difficult to remove an electron. Hence, the ionization energy increases.
03

Identify the element with the largest ionization energy.

To identify the element with the largest ionization energy, we should look for an element with the smallest atomic size, since the ionization energy and atomic size are inversely related. In the periodic table, ionization energy generally increases from left to right across a period and decreases down a group. Therefore, the element with the largest ionization energy should be located at the top-right corner of the periodic table. In this case, the element is Helium (He), which has the largest ionization energy.
04

Identify the element with the smallest ionization energy.

To identify the element with the smallest ionization energy, we should look for an element with the largest atomic size, since the ionization energy and atomic size are inversely related. In the periodic table, atomic size increases down a group and decreases from left to right across a period. Therefore, the element with the smallest ionization energy should be located at the bottom-left corner of the periodic table. In this case, the element is Francium (Fr), which has the smallest ionization energy.

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Most popular questions from this chapter

Some ions do not have a corresponding neutral atom that has the same electron configuration. For each of the following ions, identify the neutral atom that has the same number of electrons and determine if this atom has the same electron configuration. If such an atom does not exist, explain why. (a) \(\mathrm{Cl}^{-}\), (b) \(\mathrm{Sc}^{3+}\), (c) \(\mathrm{Fe}^{2+}\), (d) \(\mathrm{Zn}^{2+}\), (e) \(\mathrm{Sn}^{4+}\).

Consider the \(\mathrm{A}_{2} \mathrm{X}_{4}\) molecule depicted here, where \(\mathrm{A}\) and \(\mathrm{X}\) are elements. The A-A bond length in this molecule is \(d_{1}\), and the four \(\mathrm{A}-\mathrm{X}\) bond lengths are each \(d_{2}\). (a) In terms of \(d_{1}\) and \(d_{2}\), how could you define the bonding atomic radii of atoms \(\mathrm{A}\) and \(\mathrm{X}\) ? (b) In terms of \(d_{1}\) and \(d_{2}\), what would you predict for the \(\mathrm{X}-\mathrm{X}\) bond length of an \(\mathrm{X}_{2}\) molecule? [Section 7.3]

Write balanced equations for the following reactions: (a) potassium oxide with water, (b) diphosphorus trioxide with water, (c) chromium(III) oxide with dilute hydrochloric acid, (d) selenium dioxide with aqueous potassium hydroxide.

Little is known about the properties of astatine, At, because of its rarity and high radioactivity. Nevertheless, it is possible for us to make many predictions about its properties. (a) Do you expect the element to be a gas, liquid, or solid at room temperature? Explain. (b) Would you expect At to be a metal, nonmetal, or metalloid? Explain. (c) What is the chemical formula of the compound it forms with \(\mathrm{Na}\) ?

(a) The measured \(\mathrm{Bi}-\mathrm{Br}\) bond length in bismuth tribromide, \(\mathrm{BiBr}_{3}\), is \(2.63 \AA\). Based on this value and the data in Figure 7.8, predict the atomic radius of Bi. (b) Bismuth tribromide is soluble in acidic solution. It is formed by treating solid bismuth(III) oxide with aqueous hydrobromic acid. Write a balanced chemical equation for this reaction. (c) While bismuth(III) oxide is soluble in acidic solutions, it is insoluble in basic solutions such as \(\mathrm{NaOH}(a q)\). Based on these properties, is bismuth characterized as a metallic, metalloid, or nonmetallic element? (d) Treating bismuth with fluorine gas forms \(\mathrm{BiF}_{5}\). Use the electron configuration of \(\mathrm{Bi}\) to explain the formation of a compound with this formulation. (e) While it is possible to form \(\mathrm{BiF}_{5}\) in the manner just described, pentahalides of bismuth are not known for the other halogens. Explain why the pentahalide might form with fluorine but not with the other halogens. How does the behavior of bismuth relate to the fact that xenon reacts with fluorine to form compounds but not with the other halogens?
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