Non-Ideal Gases and the Van der Waals Equation

Professor Dave Explains

3 May 201908:09

Summary

TLDRProfessor Dave discusses non-ideal gases, contrasting them with ideal gases by highlighting the latter's assumptions of dimensionless particles and non-interacting collisions. He explains that these assumptions fail under high pressure and low temperature conditions, leading to non-ideal gas behavior. To account for this, the van der Waals equation introduces correction factors for particle volume and intermolecular forces, offering a more accurate model for real gases. An example calculation with carbon dioxide illustrates the difference between ideal and non-ideal gas laws, emphasizing the importance of using the correct model based on conditions.

Takeaways

🔬 Ideal gases are based on assumptions that may not hold true in all conditions, such as considering gas particles as dimensionless points and assuming no interactions between them.
🌡️ Non-ideal gas behavior occurs at high pressures and low temperatures where the assumptions of ideal gas behavior are no longer valid.
📉 As pressure increases or temperature decreases, the volume of gas particles and their interactions become significant, causing deviation from ideal gas laws.
🔄 The van der Waals equation accounts for non-ideal gas behavior by introducing correction factors for the volume occupied by gas particles and the attractive forces between them.
🔢 The van der Waals equation includes constants A and B, which are specific to each gas and represent the strength of intermolecular forces and the size of the gas particles, respectively.
🧮 Using the van der Waals equation provides a more accurate calculation of gas properties under non-ideal conditions compared to the ideal gas law.
🌟 The ideal gas law is a special case of the van der Waals equation, becoming accurate when the volume is large and the number of moles is small, making the correction terms negligible.
📚 The van der Waals equation reduces to the ideal gas law under ideal conditions, demonstrating the relationship between the two and the conditions for their applicability.
📈 The difference between the results from the ideal gas law and the van der Waals equation can be significant in high-pressure or low-temperature scenarios, especially for polar molecules.
🧪 Understanding the limitations and applicability of both the ideal gas law and the van der Waals equation is crucial for accurate calculations in chemical and physical systems.

Q & A

What are the two main assumptions made in the kinetic molecular theory for ideal gases?
-The two main assumptions are that gas particles are dimensionless points and that they do not interact with each other when they collide, only making totally elastic collisions.
Why are the assumptions of ideal gases not always accurate?
-The assumptions are not always accurate because in reality, gas particles do occupy a measurable volume and can participate in electrostatic interactions when they collide.
Under what conditions can the volume of gas particles be ignored in calculations?
-The volume of gas particles can be ignored when the gas is very sparse or has a very large volume compared to the volume occupied by the particles.
How do high pressures and low temperatures affect the behavior of a gas according to the script?
-High pressures and low temperatures cause a gas to deviate from ideal gas behavior because the particles are closer together and move more slowly, increasing the chance for interactions.
What is the van der Waals equation and how does it differ from the ideal gas law?
-The van der Waals equation is a correction to the ideal gas law that includes two correction factors to account for the attraction between gas particles and the volume occupied by the particles themselves.
What are the two correction factors in the van der Waals equation?
-The two correction factors are 'P + (a n^2) / (V^2)' for the pressure term, accounting for intermolecular attraction, and 'V - nb' for the volume term, accounting for the volume occupied by the gas particles.
What are the units of the constants A and B in the van der Waals equation?
-The units for constant A are pressure times volume squared per mole squared (e.g., atm L²/(mol)²), and for constant B, it is volume per mole (e.g., L/mol).
How does the van der Waals equation reduce to the ideal gas law under certain conditions?
-The van der Waals equation reduces to the ideal gas law when the volume is very large and the number of moles is very small, making the correction terms approach zero and thus negligible.
What is the significance of using the van der Waals equation over the ideal gas law in non-ideal conditions?
-Using the van der Waals equation in non-ideal conditions provides a more accurate description of gas behavior, especially at high pressures and low temperatures where intermolecular forces become significant.
How does the presence of polar molecules affect the accuracy of the ideal gas law?
-The presence of polar molecules increases the significance of intermolecular forces, making the ideal gas law less accurate as these forces can no longer be neglected.
What is the difference in pressure calculated using the ideal gas law versus the van der Waals equation for the given example in the script?
-For the given example, the ideal gas law calculates a pressure of 33.5 atmospheres, while the van der Waals equation calculates a pressure of 32.4 atmospheres.