Presentation is loading. Please wait.

Presentation is loading. Please wait.

NIKAM N.D. M.Sc.NET DEPARTMENT OF CHEMISTRY

Published byBranden Blair Modified over 5 years ago

Similar presentations

Presentation on theme: "NIKAM N.D. M.Sc.NET DEPARTMENT OF CHEMISTRY"— Presentation transcript:

1 NIKAM N.D. M.Sc.NET DEPARTMENT OF CHEMISTRY
The Meissner Effect NIKAM N.D. M.Sc.NET DEPARTMENT OF CHEMISTRY

2 Outline What is the Meissner Effect? Superconductors as diamagnets.
Meissner effect in perfect conductors? Meissner effect in superconductors.

3 The Meissner Effect A diamagnetic property exhibited by superconductors. End result is the exclusion of magnetic field from the interior of a superconductor. What is diamagnetism?

4 Diamagnetism? A superconductor is not only a perfect conductor (R=0), but a perfect diamagnet. It will tend to repel a magnet.

5 So, Superconductors are Perfect Diamagnets?
If a superconductor was only a perfect conductor, would there be a Meissner Effect? Recall Faraday’s Law of Induction.

6 Faraday’s Law of Induction

7 Faraday’s Law of Induction
A change in magnetic flux will induce an emf in a conductor. There will be no induced emf if the magnetic flux is constant with respect to time.

8 The Minus Sign What does the minus sign imply physically?
The direction of the induced emf will be such that the magnetic field produced by the induced emf resists the change in magnetic flux. The presence of the minus sign is referred to as Lenz’s Law

9 Lenz’s Law If the magnetic flux is decreasing out of the page, which way will the induced emf be directed? (Note: the induced emf has the same direction as the induced current.)

10 The direction of the induced emf (or current), will be counterclockwise.
This will generate an induced magnetic field out of the page, counteracting the decrease in flux. (Found from the right-hand rule for current carrying wires.)

11 Perfect Conductor Move this perfect conductor into a magnetic field.
By Faraday’s Law of Induction, a current is induced. The magnetic field generated by this current would oppose the change of the applied field.

12 How long will the induced current flow? Recall P= I2R.
The induced current would flow indefinitely. There is no I2R power loss. The induced magnetic field will continue to oppose the change in the applied field. Conversely, if the conductor is in a magnetic field which is then removed, an induced current and corresponding magnetic field would tend to oppose the removal of the applied field.

13 What Do We See? Would a magnet levitate over the surface of a perfect conductor? No, if a magnet is placed on top of a material which becomes a perfect conductor, there would be no effect on the magnet. There would only be an opposing force if the magnet was removed.

14 In Superconductors Faraday’s Law does not explain magnetic repulsion by superconductors. Below its critical temperature (Tc) a superconductor does not allow any magnetic field to enter it.                                   

15 Circulating currents on the surface of the superconductor induce microscopic magnetic dipoles that oppose the applied field. The induced field repels the applied field, and the magnet associated with it. If a magnet is on top of a superconductor as it is cooled below its Tc, it would exclude the magnetic field of the magnet.

16 The Result

17 References Image 1: Image 2: Image 3: Image 4:

Download ppt "NIKAM N.D. M.Sc.NET DEPARTMENT OF CHEMISTRY"

Similar presentations

Faradays Law of Induction A changing magnetic field induces an electric field. The induced electric field causes a current to flow in a conductor.

Faradays Law of Induction A changing magnetic field induces an electric field. The induced electric field causes a current to flow in a conductor.
Lenzs Law. Minus Sign There is a minus sign in Faradays Law. There is a minus sign in Faradays Law. Relates flux change to polarity of emfRelates flux.

Lenzs Law. Minus Sign There is a minus sign in Faradays Law. There is a minus sign in Faradays Law. Relates flux change to polarity of emfRelates flux.
Copyright © 2012 Pearson Education Inc. PowerPoint ® Lectures for University Physics, Thirteenth Edition – Hugh D. Young and Roger A. Freedman Lectures.

Copyright © 2012 Pearson Education Inc. PowerPoint ® Lectures for University Physics, Thirteenth Edition – Hugh D. Young and Roger A. Freedman Lectures.
Lecture 24 Faraday’s Law April 1. Electromagnetic Induction Slide 25-8.

Lecture 24 Faraday’s Law April 1. Electromagnetic Induction Slide 25-8.
Superconductivity and Superfluidity The Meissner Effect So far everything we have discussed is equally true for a “perfect conductor” as well as a “superconductor”

Superconductivity and Superfluidity The Meissner Effect So far everything we have discussed is equally true for a “perfect conductor” as well as a “superconductor”
Lenz’s Law AP Physics C Montwood High School R. Casao.

Lenz’s Law AP Physics C Montwood High School R. Casao.
Induced EMF and Inductance 1830s Michael Faraday Joseph Henry.

Induced EMF and Inductance 1830s Michael Faraday Joseph Henry.
Magnetism Lenz’s Law 1 Examples Using Lenz’s Law.

Magnetism Lenz’s Law 1 Examples Using Lenz’s Law.
Electromagnetic Induction and Faraday’s Law Physics Department, New York City College of Technology.

Electromagnetic Induction and Faraday’s Law Physics Department, New York City College of Technology.
TOC 1 Physics 212 Lenz's Law Lenz’s Law Examples Using Lenz’s Law.

TOC 1 Physics 212 Lenz's Law Lenz’s Law Examples Using Lenz’s Law.
Electromagnetic Induction Faraday’s Law. Induced Emf A magnet entering a wire causes current to move with in the wires I = Emf / R The induced current.

Electromagnetic Induction Faraday’s Law. Induced Emf A magnet entering a wire causes current to move with in the wires I = Emf / R The induced current.
Chapter 29 Electromagnetic Induction. Induced current You mean you can generate electricity this way??!

Chapter 29 Electromagnetic Induction. Induced current You mean you can generate electricity this way??!
Physics 2102 Lecture 18 Ch30: Inductors & Inductance II Physics 2102 Jonathan Dowling Nikolai Tesla.

Physics 2102 Lecture 18 Ch30: Inductors & Inductance II Physics 2102 Jonathan Dowling Nikolai Tesla.
Magnetic Induction - magnetic flux - induced emf

Magnetic Induction - magnetic flux - induced emf
Chapter 20 Electromagnetic Induction. Electricity and magnetism Generators, motors, and transformers.

Chapter 20 Electromagnetic Induction. Electricity and magnetism Generators, motors, and transformers.
Faraday’s Law of Induction.  = -N  B /  t –  : induced potential (V) – N: # loops –  B : magnetic flux (Webers, Wb) – t: time (s)

Faraday’s Law of Induction.  = -N  B /  t –  : induced potential (V) – N: # loops –  B : magnetic flux (Webers, Wb) – t: time (s)
Magnetism and magnetic forces. Current off coil Molecular magnets aligned randomly N S.

Magnetism and magnetic forces. Current off coil Molecular magnets aligned randomly N S.
Faraday’s Law.

Faraday’s Law.
Induced current produces a secondary magnetic field that is always opposed to the primary magnetic field that induced it, an effect called Lenz’s law.

Induced current produces a secondary magnetic field that is always opposed to the primary magnetic field that induced it, an effect called Lenz’s law.
P202c30: 1 Chapter30: Electromagnetic Induction Motional EMF’s Conductor Moving through a magnetic field Magnetic Force on charge carriers Accumulation.

P202c30: 1 Chapter30: Electromagnetic Induction Motional EMF’s Conductor Moving through a magnetic field Magnetic Force on charge carriers Accumulation.

Similar presentations

Ads by Google