Spontaneity, Entropy, and Free Energy

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Presentation transcript:

Spontaneity, Entropy, and Free Energy Chapter 16 Spontaneity, Entropy, and Free Energy

Figure 16.1: When methane and oxygen react to form carbon dioxide and water, the products have lower potential energy than the reactants. This change in potential energy results in energy flow (heat) to the surroundings. Copyright © Houghton Mifflin Company. All rights reserved.

Figure 16.2: The rate of a reaction depends on the pathway from reactants to products; this is the domain of kinetics. Thermodynamics tells us whether a reaction is spontaneous based only on the properties of the reactants and products. The predictions of thermodynamics do not require knowledge of the pathway between reactants and products.

Figure 16.3: The expansion of an ideal gas into an evacuated bulb. Copyright © Houghton Mifflin Company. All rights reserved.

Figure 16.4: Possible arrangements (states) of four molecules in a two-bulbed flask.

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The hypothetical contraction of a gas.

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The mineral stibnite contains Sb2S3.

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Figure 16. 5: (a) A perfect crystal of hydrogen chloride at 0 K Figure 16.5: (a) A perfect crystal of hydrogen chloride at 0 K. (b) As the temperature rises above 0 K, lattice vibrations allow some dipoles to change their orientations, producing some disorder and an increase in entropy. Copyright © Houghton Mifflin Company. All rights reserved.

Figure 16.6: The H2O molecule can vibrate and rotate in several ways, some of which are shown here.

Figure 16.7: Schematic representations of balls rolling down two types of hills. Copyright © Houghton Mifflin Company. All rights reserved.

Figure 16. 8: (a) The initial free energies of A and B Figure 16.8: (a) The initial free energies of A and B. (b) As A(g) changes to B(g), the free energy of A decreases and that of B increases. (c) Eventually, pressures of A and B are achieved such that GA = GB, the equilibrium position.

Figure 16.9: (a) The change in free energy to reach equilibrium, beginning with 1.0 mol A(g) at PA = 2.0 atm. (b) The change in free energy to reach equilibrium, beginning with 1.0 mol B(g) at PB = 2.0 atm. (c) The free energy profile for A(g) B(g) in a system containing 1.0 mol (A plus B) at PTOTAL = 2.0 atm. Each point on the curve corresponds to the total free energy of the system for a given combination of A and B. Copyright © Houghton Mifflin Company. All rights reserved.

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Figure 16.10: A battery can do work by sending current to a starter motor. Copyright © Houghton Mifflin Company. All rights reserved.