19: Thermodynamics

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Marco Zimmer-De Iuliis and Anna Galang
University of Toronto Scarborough

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This chapter explores the principles of thermochemistry, a branch of chemistry focused on the study of heat involved in chemical reactions and changes of state. Understanding thermochemical concepts is essential for grasping how energy is absorbed, released, and transformed during chemical processes. Previous chapters in this text have described various applications of thermochemistry, an important aspect of thermodynamics concerned with the heat flow accompanying chemical reactions and phase transitions. This chapter will introduce additional thermodynamic concepts, including those that enable the prediction of any chemical or physical changes under a given set of conditions.

As you delve into the concepts of thermochemistry in this chapter, consider how these principles are applied in cutting-edge research to address global energy challenges. Dr. Vonzyy's work illustrates the crucial role of thermochemistry in the innovation and development of sustainable energy solutions.

Faculty Feature

Dr. Alex Vonzyy's research focuses on thermochemistry, emphasizing the study of heat in Colorful Photo Style (4).png chemical reactions and its application in energy solutions. His team develops advanced materials for Li-ion batteries, hydrogen storage, CO₂ capture, and photovoltaics, aligning with climate change mitigation and the Paris Agreement goals. Utilizing atomistic simulations, machine learning, and automated synthesis, they rapidly create and test materials to accelerate renewable energy adoption. Dr. Vonzyy’s work highlights the critical role of thermochemical principles in designing innovative energy solutions, showcasing the connection between chemical energy transformations and global sustainability efforts.

Read more about Dr. Alex Voznyy and his research here: http://cleanenergy.utoronto.ca/

19.1: Introduction
Previous chapters in this text have described various applications of thermochemistry, an important aspect of thermodynamics concerned with the heat flow accompanying chemical reactions and phase transitions. This chapter will introduce additional thermodynamic concepts, including those that enable the prediction of any chemical or physical changes under a given set of conditions.
19.2: Enthalpy
If a chemical change is carried out at constant pressure and the only work done is caused by expansion or contraction, q for the change is called the enthalpy change with the symbol ΔH. Examples of enthalpy changes include enthalpy of combustion, enthalpy of fusion, enthalpy of vaporization, and standard enthalpy of formation. If the enthalpies of formation are available for the reactants and products of a reaction, the enthalpy change can be calculated using Hess’s law.
19.3: Spontaneity
Chemical and physical processes have a natural tendency to occur in one direction under certain conditions. A spontaneous process occurs without the need for a continual input of energy from some external source, while a nonspontaneous process requires such. Systems undergoing a spontaneous process may or may not experience a gain or loss of energy, but they will experience a change in the way matter and/or energy is distributed within the system.
19.4: Entropy
Entropy (S) is a state function that can be related to the number of microstates for a system (the number of ways the system can be arranged) and to the ratio of reversible heat to kelvin temperature. It may be interpreted as a measure of the dispersal or distribution of matter and/or energy in a system, and it is often described as representing the “disorder” of the system. For a given substance, \(S_{solid} < S_{liquid} < S_{gas}\) in a given physical state at a given temperature.
19.5: The Second and Third Laws of Thermodynamics
The second law of thermodynamics states spontaneous processes increases the entropy of the universe, \(S_{univ} > 0\). If \(ΔS_{univ} < 0\), the process is nonspontaneous, and if \(ΔS_{univ} = 0\_, the system is at equilibrium. The third law of thermodynamics establishes the zero for entropy at 0 for a perfect, pure crystalline solid at 0 K with only one possible microstate. The standard entropy change for a process is computed standard entropy values for the species involved.
19.6: Free Energy
Gibbs free energy (G) is a state function defined with regard to system quantities only and may be used to predict the spontaneity of a process. A negative value for ΔG indicates a spontaneous process; a positive ΔG indicates a nonspontaneous process; and a ΔG of zero indicates that the system is at equilibrium. A number of approaches to the computation of free energy changes are possible.
19.7: Key Terms
19.8: Key Equations
19.9: Summary
19.10: Exercises
These end-of-chapter exercises are for practice to help you both understand concepts from the course and for practice for tests and exams.

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