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Diamagnetism01:26

Diamagnetism

Materials consisting of paired electrons have zero net magnetic moments. However, when these materials are placed under an external magnetic field, the moments opposite to the field are induced. Such materials are called diamagnets. Diamagnetism is the response of the diamagnets when placed in an external magnetic field.
Diamagnetism was discovered by Anton Brugmans in 1778 when he observed that bismuth gets repelled by magnetic fields, thus theorizing that diamagnets get repelled by magnets.
Potential Due to a Magnetized Object01:24

Potential Due to a Magnetized Object

Magnetic dipoles in magnetic materials are aligned when placed under an external magnetic field. For paramagnets and ferromagnets, dipole alignment occurs in the direction of the magnetic field. However, the dipoles align opposite to the field in the case of diamagnets. This state of magnetic polarization due to the external field is called magnetization. Magnetization is defined as the dipole moment per unit volume. It plays a similar role to polarization in electrostatics.
The vector...
Magnetic Vector Potential01:15

Magnetic Vector Potential

In electrostatics, the electric field can be written as the negative gradient of the potential. In magnetostatics, the zero divergence of the magnetic field ensures that the magnetic field can be expressed as the curl of a vector potential. This potential is known as the magnetic vector potential.
Consider an ideal solenoid with n turns per unit length and radius R. If I is the current through the solenoid, the magnetic field inside the solenoid is expressed as the product of vacuum...
Magnetic Field Due To A Thin Straight Wire01:27

Magnetic Field Due To A Thin Straight Wire

Consider an infinitely long straight wire carrying a current I. The magnetic field at point P at a distance a from the origin can be calculated using the Biot-Savart law.
Magnetic Field due to Moving Charges01:23

Magnetic Field due to Moving Charges

A stationary charge creates and interacts with the electric field, while a moving charge creates a magnetic field.
Consider a point charge moving with a constant velocity. Like the electric field, the magnetic field at any point is directly proportional to the magnitude of the charge and inversely proportional to the square of the distance between the source point and the field point. However, unlike the electric field, the magnetic field is always perpendicular to the plane containing the line...
Atomic Nuclei: Nuclear Relaxation Processes01:23

Atomic Nuclei: Nuclear Relaxation Processes

In the absence of an external magnetic field, nuclear spin states are degenerate and randomly oriented. When a magnetic field is applied, the spins begin to precess and orient themselves along (lower energy) or against (higher energy) the direction of the field. At equilibrium, a slight excess population of spins exists in the lower energy state. Because the direction of the magnetic field is fixed as the z-axis,  the precessing magnetic moments are randomly oriented around the z-axis. This...

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Related Experiment Video

Updated: Jun 3, 2026

Fabrication of Magnetic Nanostructures on Silicon Nitride Membranes for Magnetic Vortex Studies Using Transmission Microscopy Techniques
06:27

Fabrication of Magnetic Nanostructures on Silicon Nitride Membranes for Magnetic Vortex Studies Using Transmission Microscopy Techniques

Published on: July 2, 2018

Vortex-in-nanodot potentials in thin circular magnetic dots.

G M Wysin1

  • 1Department of Physics, Kansas State University, Manhattan, KS 66506-2601, USA. wysin@phys.ksu.edu

Journal of Physics. Condensed Matter : an Institute of Physics Journal
|March 16, 2011
PubMed
Summary
This summary is machine-generated.

Researchers mapped magnetic vortex energy landscapes in nanodots using auxiliary fields. This method avoids rigid approximations and reveals potential bistable operation due to impurities.

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Last Updated: Jun 3, 2026

Fabrication of Magnetic Nanostructures on Silicon Nitride Membranes for Magnetic Vortex Studies Using Transmission Microscopy Techniques
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Published on: July 2, 2018

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Area of Science:

  • Condensed Matter Physics
  • Materials Science
  • Nanotechnology

Background:

  • Vortex states in magnetic nanostructures are crucial for data storage applications.
  • Understanding vortex core dynamics is essential for predicting device behavior.

Purpose of the Study:

  • To investigate the potential energy landscape of magnetic vortices in thin circular nanodots.
  • To develop a method for mapping vortex energy without rigid approximations.
  • To analyze the influence of external fields and material imperfections on vortex states.

Main Methods:

  • Utilized auxiliary constraining fields and Lagrange's method of undetermined multipliers to minimize system energy.
  • Applied a constraint on the vortex core position to map potential energy space.
  • Modeled the competition between Heisenberg exchange and demagnetization fields.

Main Results:

  • The potential energy landscape was found to be nearly parabolic with respect to vortex core position (r).
  • An auxiliary constraining field, applied only in the core region, increased linearly with r.
  • Nonmagnetic impurities or holes can induce bistable vortex operation under transverse magnetic fields.

Conclusions:

  • The auxiliary field method effectively maps vortex potential energy, closely matching rigid vortex approximations for uniform dots.
  • Material imperfections like impurities or holes can be modeled to predict bistable behavior, relevant for memory applications.