PDF (chapter_8)
PDF (chapter_8)

Pdf - Text of NPTEL IIT Video Lectures
Pdf - Text of NPTEL IIT Video Lectures

Quantum Mechanics intensive property
Quantum Mechanics intensive property

The Potential Contribution of Organic Salts to New
The Potential Contribution of Organic Salts to New

Entropy and The Second Law of Thermodynamics
Entropy and The Second Law of Thermodynamics

Vapor Pressure Diagrams and Boiling Diagrams
Vapor Pressure Diagrams and Boiling Diagrams

Biomolecular electrostatics with continuum models: a boundary
Biomolecular electrostatics with continuum models: a boundary

Enthalpy - Net Texts
Enthalpy - Net Texts

No Slide Title
No Slide Title

4.3 Notes - Denton ISD
4.3 Notes - Denton ISD

Solutions Exercises Lecture 4
Solutions Exercises Lecture 4

Calculation of reverse losses in a power diode
Calculation of reverse losses in a power diode

Measurement of Partial Molar Volumes
Measurement of Partial Molar Volumes

Changes of State
Changes of State

Click to open the TEOS-10 teaching aid slides(powerpoint)
Click to open the TEOS-10 teaching aid slides(powerpoint)

Finding Complex Solutions of Quadratic Equations
Finding Complex Solutions of Quadratic Equations

Dissipation and the so-called entropy production
Dissipation and the so-called entropy production

Chapter 19 Thermodynamics - Farmingdale State College
Chapter 19 Thermodynamics - Farmingdale State College

Thermal Flux through a Surface of n-Octane. A Non
Thermal Flux through a Surface of n-Octane. A Non

A Microscopic Approach to Van-der
A Microscopic Approach to Van-der

Chp-1. Pure substances
Chp-1. Pure substances

Solutions
Solutions

Density Functional Theory Studies of Small Supported Gold Clusters
Density Functional Theory Studies of Small Supported Gold Clusters

CHAPTER 4: THERMODYNAMICS OF AIR
CHAPTER 4: THERMODYNAMICS OF AIR

Physical-chemical properties of complex natural fluids
Physical-chemical properties of complex natural fluids

Van der Waals equation



The van der Waals equation is a thermodynamic equation describing gases and liquids (fluids) under a given set of pressure (P), volume (V), and temperature (T) conditions (i.e., it is a thermodynamic equation of state). In particular, it theorizes that fluids are composed of particles with non-zero volumes, and subject to a pairwise inter-particle attractive force. It was derived in 1873 by Johannes Diderik van der Waals, who received the Nobel Prize in 1910 for ""his work on the equation of state for gases and liquids,"" who did related work on the attractive force that bears his name. It is available via its traditional derivation (a mechanical equation of state), or via a derivation based in statistical thermodynamics, the latter of which provides the partition function of the system and allows thermodynamic functions to be specified. The resulting equation is a modification to and improvement of the ideal gas law, taking into account the nonzero size of atoms and molecules and the attraction between them. It successfully approximates the behavior of real fluids above their critical temperatures and is qualitatively reasonable for their liquid and low-pressure gaseous states at low temperatures. However, near the transitions between gas and liquid, in the range of P, V, and T where the liquid phase and the gas phase are in equilibrium, the van der Waals equation fails to accurately model observed experimental behaviour, in particular that P is a constant function of V at given temperatures. As such, the van der Waals model is useful only for teaching and qualitative purposes, but is not used for calculations intended to predict real behaviour. Empirical corrections to address these predictive deficiencies have been inserted into the van der Waals model, e.g., by James Clerk Maxwell in his equal area rule, and related but distinct theoretical models, e.g., based on the principle of corresponding states, have been developed to achieve better fits to real fluid behaviour in equations of comparable complexity.