Out of anions S 2 − , Se 2 − and O 2 − the ion that has greatest the coulombic attraction with Mg 2 + has to be identified and factors that results in such difference have to be determined. Concept Introduction: Three-dimensional array of ions constitute the ionic compound lattice. They are stabilized because of attractive forces between oppositely charged ions that lower the potential energy. Stability of ionic compound depends upon two factors and that is size and charge. Higher the charge and less will be the stability of ionic compound and vice-versa. Smaller the size of anion more will be the stability Lower is the potential energy of interaction and more stable is the ionic solid. Hence the compounds that have high charge density on small space are most stable ionic solids. For example, calcium phosphate is made up of Ca 2 + and PO 4 3 − . The highly charged ions have stronger interionic interactions and this accounts for rigidity of calcium phosphate.

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Chapter 2, Problem 2A.28E

Interpretation Introduction

Interpretation:

Out of anions S2−, Se2− and O2− the ion that has greatest the coulombic attraction with Mg2+ has to be identified and factors that results in such difference have to be determined.

Concept Introduction:

Three-dimensional array of ions constitute the ionic compound lattice. They are stabilized because of attractive forces between oppositely charged ions that lower the potential energy.

Stability of ionic compound depends upon two factors and that is size and charge. Higher the charge and less will be the stability of ionic compound and vice-versa. Smaller the size of anion more will be the stability

Lower is the potential energy of interaction and more stable is the ionic solid. Hence the compounds that have high charge density on small space are most stable ionic solids. For example, calcium phosphate is made up of Ca2+ and PO43−. The highly charged ions have stronger interionic interactions and this accounts for rigidity of calcium phosphate.

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