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Chapter 10: Problem 11

Why do gases behave nonideally at high pressures and low temperatures?

Short Answer

Expert verified
Answer: Gases display non-ideal behavior at high pressures and low temperatures because the assumptions made in the ideal gas law, such as the volume occupied by gas particles being negligible and the absence of intermolecular forces, are no longer valid under these conditions. High pressures compress the gas particles and force them closer together, causing the volume assumption to break down and intermolecular forces to become more significant. Similarly, low temperatures result in slower particle movement, allowing intermolecular forces to play a more significant role. These factors cause deviations from the ideal gas behavior as described by the ideal gas law equation.

Step by step solution

01

Ideal Gas Law and Assumptions

The ideal gas law is given by the equation PV=nRT, where P is the pressure, V is the volume, n is the number of moles, R is the ideal gas constant, and T is the temperature. The ideal gas model is based on several assumptions: (1) gas particles are in constant, random motion with elastic collisions, (2) the volume occupied by the gas particles is negligible compared to the volume of the container, and (3) there are no attractive or repulsive forces between gas particles.
02

High Pressures

At high pressures, the gas particles are compressed and forced to occupy a smaller volume. This results in the particles being much closer together, which means that the assumption of negligible volume occupied by gas particles no longer holds true. Additionally, as the particles are closer together, the intermolecular forces (attractive and repulsive) between particles start to play a more significant role in their behavior. These factors cause deviation from the ideal gas law behavior at high pressures.
03

Low Temperatures

At low temperatures, the gas particles have less kinetic energy, which means they are moving more slowly. This slower movement allows the intermolecular forces between particles to become more significant, as there is more time for particles to interact with one another. This means that assumption (3), which states that there are no attractive or repulsive forces between gas particles, is no longer valid. As a result, gas behavior deviates from the ideal gas law at low temperatures. In conclusion, gases behave nonideally at high pressures and low temperatures because the assumptions made in the ideal gas law, such as the volume occupied by gas particles being negligible and the absence of intermolecular forces, are no longer valid under these conditions. This causes deviations from the ideal gas behavior as described by the ideal gas law equation.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Ideal Gas Law
The Ideal Gas Law is a cornerstone in understanding gas behavior, represented by the equation \( PV = nRT \). Here, \( P \) stands for pressure, \( V \) for volume, \( n \) is the number of moles, \( R \) is the ideal gas constant, and \( T \) is the temperature. This law arises from several assumptions about gas particles:
  • Gas particles are in constant, random motion and collide elastically.
  • The volume of gas particles themselves is negligible compared to the container's volume.
  • No attractive or repulsive forces act between the gas particles.
These assumptions help us model real gases under certain conditions, enabling predictions about their behavior in theoretical frameworks. Nonetheless, these assumptions break down under high-pressure or low-temperature conditions, which leads to nonideal behavior.
Intermolecular Forces
Intermolecular forces refer to the attractive or repulsive interactions occurring between molecules. Although often negligible for gases at high temperatures and low pressures, these forces become pivotal under different circumstances.

When particles come closer, such as at higher pressures or when they move more slowly at low temperatures, these interactions cannot be ignored.
  • Attractive forces include van der Waals forces, responsible for drawing particles closer.
  • Repulsive forces occur when particles overlap or are pushed too close together.
These forces cause deviations from ideal gas predictions, altering properties like pressure and volume significantly as they become non-negligible. Understanding these forces is critical in accurately predicting gas behavior, especially in nonideal conditions.
High Pressure Effects
At high pressures, the gas particles are forced closer together. In this scenario, the assumptions of the Ideal Gas Law start crumbling.
  • The actual volume occupied by the gas particles becomes significant and cannot be neglected.
  • Intermolecular forces, which would normally be negligible, start affecting how particles interact.
This leads to a measurable deviation from ideal behavior, often resulting in larger pressures than predicted by the ideal gas equation. To account for this, modified equations such as the Van der Waals equation are used, incorporating factors for particle volume and intermolecular forces.
Low Temperature Effects
Low temperatures result in decreased kinetic energy for gas particles, meaning they move slower. This has substantial effects on their behavior due to prolonged interaction times between particles.

When kinetic energy is low:
  • The particles spend more time in close proximity, enhancing the impact of intermolecular forces.
  • Attractive forces become more significant, potentially pulling particles together and reducing volume.
These conditions cause gases to deviate from the ideal gas predictions, often causing them to liquefy or behave more like liquids. Understanding these phenomena is vital for applications in cryogenics and for predicting weather patterns in cold regions.

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Explain why water climbs higher in a capillary tube than in a test tube.

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