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The Van der Waals Equation01:26

The Van der Waals Equation

222
The ideal gas law is based on two simplifying assumptions: first, that there are no intermolecular attractions between gas molecules, and second, that the volume occupied by the molecules themselves is negligible compared with the volume of the container. However, these assumptions don't hold up under all conditions - specifically, at high pressures and low temperatures, as gas tends to deviate from ideal gas behavior.The van der Waals equation is an enhanced version of the ideal gas law,...
222
Van der Waals Equation01:10

Van der Waals Equation

4.8K
The ideal gas law is an approximation that works well at high temperatures and low pressures. The van der Waals equation of state (named after the Dutch physicist Johannes van der Waals, 1837−1923) improves it by considering two factors.
First, the attractive forces between molecules, which are stronger at higher densities and reduce the pressure, are considered by adding to the pressure a term equal to the square of the molar density multiplied by a positive coefficient a. Second, the...
4.8K
Ideal Solutions02:24

Ideal Solutions

17.6K
According to Raoult’s law, the partial vapor pressure of a solvent in a solution is equal or identical to the vapor pressure of the pure solvent multiplied by its mole fraction in the solution. However, Raoult's Law is only valid for ideal solutions. For a solution to be ideal, the solvent-solute interaction must be just as strong as a solvent-solvent or solute-solute interaction. This suggests that both the solute and the solvent would use the same amount of energy to escape to the...
17.6K
Reaction Quotient02:35

Reaction Quotient

47.8K
The status of a reversible reaction is conveniently assessed by evaluating its reaction quotient (Q). For a reversible reaction described by m A + n B ⇌ x C + y D, the reaction quotient is derived directly from the stoichiometry of the balanced equation as
47.8K
Real Gases: Effects of Intermolecular Forces and Molecular Volume Deriving Van der Waals Equation04:01

Real Gases: Effects of Intermolecular Forces and Molecular Volume Deriving Van der Waals Equation

30.7K
Thus far, the ideal gas law, PV = nRT, has been applied to a variety of different types of problems, ranging from reaction stoichiometry and empirical and molecular formula problems to determining the density and molar mass of a gas. However, the behavior of a gas is often non-ideal, meaning that the observed relationships between its pressure, volume, and temperature are not accurately described by the gas laws.
30.7K
Equilibrium Conditions for a Particle01:23

Equilibrium Conditions for a Particle

2.4K
When an object is in equilibrium, it is either at rest or moving with a constant velocity. There are two types of equilibrium: static and dynamic. Static equilibrium occurs when an object is at rest, while dynamic equilibrium occurs when an object is moving with a constant velocity. In both cases, there must be a balance of forces acting on the object.
To understand the concept of equilibrium, let us first consider the forces acting on an object. When different forces act on an object, they can...
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Related Experiment Video

Updated: May 4, 2026

An Analog Macroscopic Technique for Studying Molecular Hydrodynamic Processes in Dense Gases and Liquids
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An Analog Macroscopic Technique for Studying Molecular Hydrodynamic Processes in Dense Gases and Liquids

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Quasirelativistic Langevin equation.

A V Plyukhin1

  • 1Department of Mathematics, Saint Anselm College, Manchester, New Hampshire 03102, USA.

Physical Review. E, Statistical, Nonlinear, and Soft Matter Physics
|December 17, 2013
PubMed
Summary
This summary is machine-generated.

This study derives the Langevin equation for relativistic Brownian motion, revealing that nonlinear dissipation terms arise from both relativistic effects and classical approximations. These terms significantly influence the particle's behavior.

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Area of Science:

  • Statistical Mechanics
  • Relativistic Quantum Mechanics
  • Nonlinear Dynamics

Background:

  • The Langevin equation describes Brownian motion, but its relativistic generalization is complex.
  • Previous models often neglect classical corrections beyond weak-coupling approximations.

Purpose of the Study:

  • To microscopically derive the Langevin equation for a weakly relativistic Brownian particle.
  • To investigate the interplay between relativistic corrections and classical nonlinear dissipation terms.

Main Methods:

  • Adoption of a noncovariant Hamiltonian model.
  • Relativistic description of free particle motion.
  • Classical treatment of particle interactions via potentials.

Main Results:

  • Relativistic corrections manifest as nonlinear dissipation terms due to velocity-momentum dependence.
  • Classical, nonrelativistic corrections also yield similar nonlinear dissipation forces.
  • These classical corrections can be as significant as relativistic ones.

Conclusions:

  • The leading nonlinear dissipation term in the relativistic Langevin equation is determined by the combined effects of relativistic and classical corrections.
  • Ignoring classical beyond-weak-coupling contributions can qualitatively alter the predicted behavior of relativistic Brownian particles.