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Dielectric Polarization in a Capacitor01:31

Dielectric Polarization in a Capacitor

The presence of a dielectric medium in a capacitor not only changes the voltage and capacitance but also affects the electric field. In general, dielectrics can be of two types: polar and nonpolar. In a polar dielectric, the positive and negative charges in the molecules are separated by a distance and hence have a permanent dipole moment. In contrast, no such charge separation exists in a nonpolar dielectric, however the nonpolar molecules get polarized in the presence of an external electric...
Electrostatic Boundary Conditions in Dielectrics01:27

Electrostatic Boundary Conditions in Dielectrics

When an electric field passes from one homogeneous medium to another, crossing the boundary between the two mediums imparts a discontinuity in the electric field. This results in electrostatic boundary conditions that depend on the type of mediums the field propagates through.
Consider a case where both the mediums across a boundary are two different dielectric materials. Recall that the electric field and electric displacement are proportional and related through the material's permittivity.
Gauss's Law in Dielectrics01:17

Gauss's Law in Dielectrics

Consider a polar dielectric placed in an external field. In such a dielectric, opposite charges on adjacent dipoles neutralize each other, such that the net charge within the dielectric is zero. When a polar dielectric is inserted in between the capacitor plates, an electric field is generated due to the presence of net charges near the edge of the dielectric and the metal plates interface. Since the external electrical field merely aligns the dipoles, the dielectric as a whole is neutral. An...
Potential Due to a Polarized Object01:29

Potential Due to a Polarized Object

A neutral atom consists of a positively charged nucleus surrounded by a negatively charged electron cloud. When placed in an external electric field, the external electric force pulls the electrons and nucleus apart, opposite to the intrinsic attraction between the nucleus and the electrons. The opposing forces balance each other with a slight shift between the center of masses of the nucleus and the electron cloud, resulting in a polarized atom. On the other hand, a few molecules, like water,...
Capacitor With A Dielectric01:18

Capacitor With A Dielectric

Parallel plate capacitors consist of two conducting plates separated by a certain distance. However, it is mechanically difficult to hold the large plates parallel to each other without actual contact. Hence, a dielectric layer is commonly placed between the plates, which provides an easy solution for holding the plates together with a small gap and increases the capacitance of the capacitor.
Dielectrics are non-conducting materials with no free or loosely bound electrons. When a dielectric is...
Intermolecular Forces03:13

Intermolecular Forces

Atoms and molecules interact through bonds (or forces): intramolecular and intermolecular. The forces are electrostatic as they arise from interactions (attractive or repulsive) between charged species (permanent, partial, or temporary charges) and exist with varying strengths between ions, polar, nonpolar, and neutral molecules. The different types of intermolecular forces are ion–dipole, dipole–dipole, hydrogen bonds, and dispersion; among these, dipole–dipole, hydrogen bonds, and dispersion...

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Related Experiment Video

Updated: Jun 27, 2026

The Preparation of Electrohydrodynamic Bridges from Polar Dielectric Liquids
10:03

The Preparation of Electrohydrodynamic Bridges from Polar Dielectric Liquids

Published on: September 30, 2014

Ion correlation forces between uncharged dielectric walls.

Erik Wernersson1, Roland Kjellander

  • 1Department of Chemistry, University of Gothenburg, SE-412 96 Gothenburg, Sweden.

The Journal of Chemical Physics
|December 3, 2008
PubMed
Summary

Investigating uncharged planar walls in electrolyte solutions reveals that ion valency and wall interactions create repulsive barriers at separations of 1-2 nm. Asymmetric ion-wall forces lead to electric double layers, mimicking charged surface interactions.

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Last Updated: Jun 27, 2026

The Preparation of Electrohydrodynamic Bridges from Polar Dielectric Liquids
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AC Electrokinetic Phenomena Generated by Microelectrode Structures
20:38

AC Electrokinetic Phenomena Generated by Microelectrode Structures

Published on: July 28, 2008

Area of Science:

  • Physical Chemistry
  • Colloid and Surface Science
  • Computational Nanoscience

Background:

  • Interactions between uncharged surfaces in electrolyte solutions are crucial for understanding phenomena like colloid stability and membrane transport.
  • Existing models often simplify or neglect the complex interplay of ionic image charges, dispersion forces, and ion correlations near interfaces.

Purpose of the Study:

  • To investigate the interaction pressure between two uncharged planar walls immersed in electrolyte solutions.
  • To self-consistently incorporate ionic image charge and ion-wall dispersion interactions.
  • To analyze the effects of ion valency and dispersion asymmetry on the wall-wall interaction.

Main Methods:

  • The study employs the anisotropic hypernetted chain (AHNC) method to model a primitive electrolyte solution between two planar walls.
  • It self-consistently calculates ion density profiles and ion-ion correlation functions, including image charge and dispersion interactions.
  • The model considers hydrocarbon/water interfaces with electrolyte concentrations from 0.250 M to 1.00 M.

Main Results:

  • Asymmetries in ion valency and dispersion interactions create electric double layers, leading to charged-surface-like interactions at large separations.
  • A repulsive pressure peak, around 1-2 nm separation, can exceed van der Waals attraction, forming a repulsive barrier.
  • Monovalent anions with strong dispersion forces in 2:1 electrolytes cause the strongest repulsion; lower valency ions are more affected by dispersion forces.

Conclusions:

  • Ion-wall dispersion and image charge forces, along with confinement effects, significantly influence the interaction pressure between uncharged walls.
  • Asymmetric ion-wall interactions can induce repulsion between uncharged surfaces, a phenomenon critical for interfacial phenomena.
  • The study highlights the importance of considering detailed ionic interactions for accurate predictions in electrolyte systems.