Instructional Video9:57
Gases Instructional Video
Bozeman Science

Gases

12th - Higher Ed
In this video Paul Andersen explains how gases differ from the other phases of matter. An ideal gas is a model that allows scientists to predict the movement of gas under varying pressure, temperature and volume. A description of both...
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Instructional Video7:00
Intermolecular Forces Instructional Video
Bozeman Science

Intermolecular Forces

12th - Higher Ed
In this video Paul Andersen explains how intermolecular forces differ from intramolecular forces. He then explains how differences in these forces account for different properties in solid, liquids and gases. Some of these properties...
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Instructional Video13:44
Plotting Potential Energy versus Intermolecular Radii Instructional Video
Catalyst University

Plotting Potential Energy versus Intermolecular Radii

Higher Ed
Plotting Potential Energy versus Intermolecular Radii
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Instructional Video6:21
Real Gas Behavior | Principle of Corresponding States [Example #2] Instructional Video
Catalyst University

Real Gas Behavior | Principle of Corresponding States [Example #2]

Higher Ed
In this video, I work a second example problem using the principle of corresponding states. -Find the temperature and pressure at which a gas behaves as another gas.
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Instructional Video6:51
Real Gas Behavior | The Hard Shell Model [Example #1] Instructional Video
Catalyst University

Real Gas Behavior | The Hard Shell Model [Example #1]

Higher Ed
Here, I work an example in which pressure is calculated using the Hard Shell gas model. We then compare it to that calculated using the ideal gas model. ***Next Example: https://youtu.be/DdCoxgpLD3U
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Instructional Video8:06
Real Gas Behavior | The Hard Shell Model [Example #2] Instructional Video
Catalyst University

Real Gas Behavior | The Hard Shell Model [Example #2]

Higher Ed
In this video, we work with the Hard Shell gas mode to calculate the work done by an expanding gas. Uses integration calculus.
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Instructional Video6:26
Real Gas Behavior | Determine the Boyle Temperature [Example #1] Instructional Video
Catalyst University

Real Gas Behavior | Determine the Boyle Temperature [Example #1]

Higher Ed
In this video, we calculate the Boyle Temperature of a real gas using the compression factor formula.
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Instructional Video7:19
Virial Equation of State & The Boyle Temperature Instructional Video
Catalyst University

Virial Equation of State & The Boyle Temperature

Higher Ed
Virial Equation of State & The Boyle Temperature
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Instructional Video7:23
Real Gas Behavior | Fugacity & Equilibrium Instructional Video
Catalyst University

Real Gas Behavior | Fugacity & Equilibrium

Higher Ed
Fugacity can be related to the equilibrium constant just like pressure. In this video, we derive an expression for the Kf (fugacity equilibrium constant) using Kp and the fugacity coefficients.
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Instructional Video4:56
Real Gas Behavior | The Compression Factor (Z) [Example #2] Instructional Video
Catalyst University

Real Gas Behavior | The Compression Factor (Z) [Example #2]

Higher Ed
Here, I work a second example in which we calculate a real gas's compression factor.
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Instructional Video
Sophia: Ideal Gas Instructional Video
Sophia Learning

Sophia: Ideal Gas

9th - 10th
A narrated screencast that explains ideal gas, and provides examples of real gases that behave as ideal gases. [2:17]
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