Ideal Gases
Master the behavior and properties of ideal gases, from monatomic to polyatomic systems, with applications in statistical thermodynamics.
Master the behavior and properties of ideal gases, from monatomic to polyatomic systems, with applications in statistical thermodynamics.
This course cannot be purchased separately - to access the complete learning experience, graded assignments, and earn certificates, you'll need to enroll in the full Statistical Thermodynamics Specialization program. You can audit this specific course for free to explore the content, which includes access to course materials and lectures. This allows you to learn at your own pace without any financial commitment.
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What you'll learn
Analyze monatomic, diatomic, and polyatomic ideal gases behavior
Describe pure ideal gases and gas mixtures applications
Master partition functions for molecular motion
Apply computational methods for equilibrium calculations
Understand industrial applications of ideal gas properties
Skills you'll gain
This course includes:
1.7 Hours PreRecorded video
5 quizzes
Access on Mobile, Tablet, Desktop
FullTime access
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There are 3 modules in this course
This comprehensive course explores ideal gas behavior through statistical thermodynamics, focusing on systems where intermolecular forces are negligible. Students analyze partition functions for translational, rotational, vibrational, and electronic motion in monatomic, diatomic, and polyatomic gases. The curriculum covers both pure gases and mixtures, including computational methods for equilibrium properties and practical industrial applications.
Simple Ideal Gas Property Relations
Module 1 · 2 Hours to complete
Mixtures
Module 2 · 1 Hours to complete
Photon and Electron Gases
Module 3 · 1 Hours to complete
Fee Structure
Instructor
Professor of Mechanical Engineering
John W. Daily is a Professor of Mechanical Engineering at the University of Colorado Boulder, specializing in combustion and reacting flows. His research focuses on understanding the behavior of reacting systems to enhance control, improve safety, and mitigate harmful health effects in various applications, including propulsion, wildland fire management, biomass utilization, and material processing. Professor Daily's work aims to provide insights that can lead to safer and more efficient combustion processes.In addition to his research in combustion, Professor Daily is also interested in medical instrumentation and is a co-founder of Precision Biopsy, a company dedicated to developing optical methods for cancer diagnosis. He teaches courses such as "Dense Gases, Liquids and Solids," "Fundamentals of Macroscopic and Microscopic Thermodynamics," and "Quantum Mechanics," equipping students with essential knowledge in thermodynamics and fluid mechanics. Through his innovative teaching and impactful research, John W. Daily continues to contribute significantly to the fields of mechanical engineering and biomedical applications at CU Boulder.
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