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Chapter 12: Problem 42

Determine if each statement is true or false: (a) Substitutional alloys are solid solutions, but interstitial alloys are heterogenous alloys. (b) Substitutional alloys have "solute" atoms that replace "solvent" atoms in a lattice, but interstitial alloys have "solute" atoms that are in between the "solvent" atoms in a lattice. (c) The atomic radii of the atoms in a substitutional alloy are similar to each other, but in an interstitial alloy, the interstitial atoms are a lot smaller than the host lattice atoms.

Short Answer

Expert verified
(a) False: Both substitutional and interstitial alloys are solid solutions. (b) True: Substitutional alloys have solute atoms that replace solvent atoms in the lattice, while interstitial alloys have solute atoms in the interstitial spaces between solvent atoms. (c) True: In substitutional alloys, atomic radii of atoms are similar, while in interstitial alloys, interstitial atoms are smaller than host lattice atoms.

Step by step solution

01

Statement (a) Analysis

A substitutional alloy is a type of solid solution where the solute atoms replace the solvent atoms in a lattice. An interstitial alloy, on the other hand, has solute atoms that occupy the spaces between the solvent atoms in the lattice. The classification of alloys as either solid solution or heterogeneous is essential for determining whether the statement is true or false.
02

Statement (a) Conclusion

The statement is false. Both substitutional and interstitial alloys are solid solutions. The difference between them lies in how the solute atoms interact with the solvent atoms' lattice and not in their classification as solid solutions or heterogeneous alloys.
03

Statement (b) Analysis

We need to examine the distribution of solute atoms in substitutional and interstitial alloys. A substitutional alloy forms when the solute atoms replace the solvent atoms in a lattice, whereas interstitial alloys form as the solute atoms occupying the interstitial spaces between solvent atoms in the lattice.
04

Statement (b) Conclusion

The statement is true. Substitutional alloys have "solute" atoms that replace the "solvent" atoms in the lattice, whereas interstitial alloys have "solute" atoms that reside in the interstitial spaces between the "solvent" atoms in the lattice.
05

Statement (c) Analysis

For this statement, we need to compare the atomic radii of the atoms in substitutional and interstitial alloys. The atomic radii of atoms in a substitutional alloy are similar to each other, as they can replace each other in a lattice. In contrast, interstitial alloys have smaller interstitial atoms than the host lattice atoms.
06

Statement (c) Conclusion

The statement is true. The atomic radii of the atoms in a substitutional alloy are similar to each other, allowing the solute and solvent atoms to replace each other in the lattice. In an interstitial alloy, the interstitial atoms are relatively small compared to the host lattice atoms, which enables them to fit in the spaces between the lattice atoms.

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Most popular questions from this chapter

(a) What are the \(\mathrm{C}-\mathrm{C}-\mathrm{C}-\mathrm{C}\) bond angles in diamond? (b) What are they in graphite (in one sheet)? (c) What atomic orbitals are involved in the stacking of graphite sheets with each other?

(a) Draw a picture that represents a crystalline solid at the atomic level. (b) Now draw a picture that represents an amorphous solid at the atomic level.

Sodium metal (atomic weight 22.99 \(\mathrm{g} / \mathrm{mol}\) ) adopts a body- centered cubic structure with a density of 0.97 \(\mathrm{g} / \mathrm{cm}^{3}\) . (a) Use this information and Avogadro's number \(\left(N_{\mathrm{A}}=6.022 \times 10^{23} / \mathrm{mol}\right)\) to estimate the atomic radius of sodium. \((\mathbf{b})\) If sodium didn't react so vigorously, it could float on water. Use the answer from part (a) to estimate the density of Na if its structure were that of a cubic close packed metal. Would it still float on water?

One method to synthesize ionic solids is by the heating of two reactants at high temperatures. Consider the reaction of FeO with \(\mathrm{TiO}_{2}\) to form FeTiO \(_{3} .\) Determine the amount of each of the two reactants to prepare 2.500 \(\mathrm{g}\) FeTiO \(_{3},\) assuming the reaction goes to completion. (a) Write a balanced chemical reaction. (b) Calculate the formula weight of FeTiO_{3} . (c) Determine the moles of FeTiO_{3} . (d) Determine moles and mass (g) of FeO required. (e) Determine moles and mass (g) of TiO_ \(_{2}\) required.

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