Textbook Question
Which of these processes are nonspontaneous? Are the nonspontaneous processes impossible? a. a bike going up a hill b. a meteor falling to Earth c. obtaining hydrogen gas from liquid water d. a ball rolling down a hill
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Ch.19 - Free Energy & Thermodynamics
Tro6th EditionChemistry: A Molecular ApproachISBN: 9780137832217
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Table of contents
- Ch.1 - Matter, Measurement & Problem Solving90
- Ch.2 - Atoms & Elements94
- Ch.3 - Molecules and Compounds103
- Ch.4 - Chemical Reactions and Chemical Quantities46
- Ch.5 - Introduction to Solutions and Aqueous Solutions65
- Ch.6 - Gases100
- Ch.7 - Thermochemistry85
- Ch.8 - The Quantum-Mechanical Model of the Atom51
- Ch.9 - Periodic Properties of the Elements79
- Ch.10 - Chemical Bonding I: The Lewis Model70
- Ch.11 - Chemical Bonding II: Molecular Shapes, VSEPR & MO Theory68
- Ch.12 - Liquids, Solids & Intermolecular Forces44
- Ch.13 - Solids & Modern Materials42
- Ch.14 - Solutions77
- Ch.15 - Chemical Kinetics88
- Ch.16 - Chemical Equilibrium57
- Ch.17 - Acids and Bases121
- Ch.18 - Aqueous Ionic Equilibrium126
- Ch.19 - Free Energy & Thermodynamics80
- Ch.20 - Electrochemistry87
- Ch.21 - Radioactivity & Nuclear Chemistry61
- Ch.22 - Organic Chemistry114
Chapter 19, Problem 30
Two systems, each composed of three particles represented by circles, have 30 J of total energy. How many energetically equivalent ways can you distribute the particles in each system? Which system has greater entropy?
Verified step by step guidance1
insert step 1> Identify the two systems and the particles within each system. Each system has three particles, and the total energy is 30 J.
insert step 2> Consider the possible energy distributions for each system. For example, you can distribute the energy among the particles in different ways, such as (10 J, 10 J, 10 J), (15 J, 10 J, 5 J), etc.
insert step 3> Calculate the number of energetically equivalent ways to distribute the energy among the particles in each system. This involves finding all possible combinations of energy distributions that sum up to 30 J.
insert step 4> Compare the number of energetically equivalent ways for each system. The system with more ways to distribute the energy has greater entropy.
insert step 5> Conclude which system has greater entropy based on the number of energetically equivalent distributions. The system with more distributions has higher entropy, as entropy is a measure of the number of possible configurations.
Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Statistical Mechanics
Statistical mechanics is a branch of physics that uses statistical methods to explain the thermodynamic properties of systems composed of a large number of particles. It provides a framework for understanding how the microscopic behavior of particles relates to macroscopic properties like temperature and energy distribution. In this context, it helps determine the number of ways particles can be arranged, which is crucial for calculating entropy.
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Reaction Mechanism Overview
Entropy
Entropy is a measure of the disorder or randomness in a system, often interpreted as the number of ways a system can be arranged while maintaining the same energy. In thermodynamics, higher entropy indicates a greater number of possible configurations, which corresponds to a more disordered state. When comparing two systems, the one with higher entropy is considered to have greater disorder and is thermodynamically favored.
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02:46Entropy in Thermodynamics
Microstates and Macrostates
In statistical mechanics, a macrostate is defined by macroscopic properties like energy and particle number, while microstates are the specific arrangements of particles that correspond to a given macrostate. The number of microstates associated with a macrostate is directly related to the entropy of the system. Understanding the relationship between microstates and macrostates is essential for calculating the entropy and determining which system has greater disorder.
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Related Practice
Textbook Question
Without doing any calculations, determine the sign of ΔSsys for each chemical reaction. a. 2 KClO3(s) → 2 KCl(s) + 3 O2(g) c. Na(s) + 2 Cl2(g) → NaCl(s) d. N2(g) + 3 H2(g) → 2 NH3(g)
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Textbook Question
Two systems, each composed of two particles represented by circles, have 20 J of total energy. Which system, A or B, has the greater entropy? Why?
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Textbook Question
Calculate the change in entropy that occurs in the system when 1.50 mol of diethyl ether (C4H10O) condenses from a gas to a liquid at its normal boiling point (34.6 °C). See Table 12.7 for heats of vaporization.
Textbook Question
Which of these processes is spontaneous? a. the combustion of natural gas b. the extraction of iron metal from iron ore c. a hot drink cooling to room temperature d. drawing heat energy from the ocean's surface to power a ship
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Textbook Question
Calculate the change in entropy that occurs in the system when 1.50 mol of isopropyl alcohol (C3H8O) melts at its melting point (-89.5 °C). See Table 12.9 for heats of fusion.
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