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Chapter 19: Problem 33

Would each of the following changes increase, decrease, or have no effect on the number of microstates available to a system: (a) increase in temperature, (b) decrease in volume, (c) change of state from liquid to gas?

Short Answer

Expert verified
(a) An increase in temperature would increase the number of microstates available to a system, as more energy levels become accessible to the particles. (b) A decrease in volume would decrease the number of microstates available to a system, as there are fewer spatial arrangements of particles possible in the system. (c) A change of state from liquid to gas would increase the number of microstates available to a system, as the particles gain more freedom to move and occupy larger volumes.

Step by step solution

01

Scenario A: Increase in Temperature

When the temperature of a system increases, the kinetic energy of its particles also increases. This means that more energy levels become accessible to the particles. As more energy levels become accessible, the number of possible arrangements of particles among these energy levels increases, which results in an increase in the number of microstates. Therefore, an increase in temperature would increase the number of microstates available to a system.
02

Scenario B: Decrease in Volume

When the volume of a system decreases while the number of particles remains constant, the particles become more confined in space. This leads to fewer spatial arrangements of particles possible in the system. As there are fewer spatial arrangements, the number of microstates available to the system decreases. Therefore, a decrease in volume would decrease the number of microstates available to a system.
03

Scenario C: Change of State from Liquid to Gas

When a system undergoes a phase transition from liquid to gas, the particles within the system gain more freedom to move and occupy larger volumes. This increased freedom of movement allows for more spatial arrangements of particles among various energy levels. As a result, the number of microstates available to the system increases. Therefore, a change of state from liquid to gas would increase the number of microstates available to a system.

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Most popular questions from this chapter

Which of the following processes are spontaneous: (a) the melting of ice cubes at \(-10^{\circ} \mathrm{C}\) and 1 atm pressure; (b) separating a mixture of \(\mathrm{N}_{2}\) and \(\mathrm{O}_{2}\) into two separate samples, one that is pure \(\mathrm{N}_{2}\) and one that is pure \(\mathrm{O}_{2}\) (c) alignment of iron filings in a magnetic field; (d) the reaction of hydrogen gas with exygen gas to form water vapor at room temperature; (e) the dissolution of HCl(g) in water to form concentrated hydrochloric acid?

The normal freezing point of \(n\)-octane \(\left(\mathrm{C}_{1} \mathrm{H}_{2 n}\right)\) is \(-57^{\circ} \mathrm{C}\). (a) Is the freezing of \(n\)-octane an endothermic or exothermic process? (b) In what temperature range is the freezing of \(n\)-octane a spontaneous process? (c) In what temperature range is it a nonspontaneous process? (d) Is there any temperature at which liquid \(n\)-octane and solid \(n\)-octane are in equilibrium? Explain.

Consider the vaporization of liquid water to steam at a pressure of \(1 \mathrm{~atm}\). (a) Is this process endothermic or exothermic? (b) In what temperature range is it a spontaneous process? (c) In what temperature range is it a nonspontaneous process? (d) At what temperature are the two phases in equilibrium?

(a) Which of the thermodynamic quantities \(T, E, q, w\), and \(S\) are state functions? (b) Which depend on the path taken from one state to another? (c) How many reversible paths are there between two states of a system? (d) For a reversible isothermal process, write an expression for \(\Delta E\) in terms of \(q\) and w and an expression for \(\Delta S\) in terms of \(q\) and \(T\).

(a) Is the standard free-energy change, \(\Delta G^{a}\), always larger than \(\Delta G\) ? (b) For any process that occurs at constant temperature and pressure, what is the significance of \(\Delta G=0\) ? (c) For a certain process, \(\Delta G\) is large and negative. Does this mean that the process necessarily has a low activation barrier?
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