Welcome to Statistical and Thermal Physics, a collection of information and resources for teachers of Statistical and Thermal Physics. The resources in this collection are supplements to standard Statistical and Thermal Physics textbooks and include student activities, background information, and applications. New users may create an account to personalize their use of the Statistical and Thermal Physics web site. This will allow them to suggest resources, add comments, and organize resources.
The elusive chemical potential
This article provides three "meanings" for the chemical potential and gives two applications to illustrate the chemical potential in action.
Teaching Statistical Physics by Thinking about Models and Algorithms
This article discusses several ways of illustrating fundamental concepts in statistical and thermal physics by considering various models and algorithms. It emphasizes the importance of replacing students' incomplete mental images by models that are physically accurate.
STP Ising 1D Program
The STP 1D Ising program is a Monte Carlo simulation of a one-dimensional Ising model in equilibrium with a heat bath at temperature T using the Metropolis algorithm.
Text, simulation and other resources for Statistical and Thermal Physics by H. Gould and J. Tobochnik.
- Chapter 1: From Microscopic to Macroscopic Behavior
- Chapter 2: Thermodynamic Concepts and Processes
- Chapter 3: Concepts of Probability
- Chapter 4: The Methodology of Statistical Mechanics
- Chapter 5: Magnetic Systems
- Chapter 6: Many-Particle Systems
- Chapter 7: Chemical Potential and Phase Equilibria
- Chapter 8: Classical Gases and Liquids
- Chapter 9: Landau Theory and the Renormalization Group
Multiple Coin Toss Model
The Multiple Coin Toss model displays the result of the flipping of N coins. It was created using the Easy Java Simulations (Ejs) modeling tool which allows a student to easily examine or modify the simulation if Ejs is installed.
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|Jul 28||Lennard-Jones 2D Metropolis Model|
|Apr 30||Student understanding of the ideal gas law, Part II: A microscopic perspective|
|Jan 8||Boltzmann Distribution from a Microcanonical Ensemble Model|
|Jan 4||Biophysics Course|