Presentation is loading. Please wait.

Presentation is loading. Please wait.

Fundamentals of Magnetism T. Stobiecki. Definitions of magnetic fields Induction: External magnetic field: Magnetizationaverage magnetic moment of magnetic.

Published bySavanna Dager Modified over 9 years ago

Similar presentations

Presentation on theme: "Fundamentals of Magnetism T. Stobiecki. Definitions of magnetic fields Induction: External magnetic field: Magnetizationaverage magnetic moment of magnetic."— Presentation transcript:

1 Fundamentals of Magnetism T. Stobiecki

2 Definitions of magnetic fields Induction: External magnetic field: Magnetizationaverage magnetic moment of magnetic material Susceptibility tensor representing anisotropic material where:permability of the material

3 Maxwell’s equations [oe] [A/m]

4 Demagnetization field poles density, magnetic „charge” density

5 Demagnetization field To compute the demagnetization field, the magnetization at all points must be known. when magnetic materials becomes magnetized by application of external magnetic field, it reacts by generating an opposing field. [emu/cm 4 ] The magnetic field caused by magnetic poles can be obtained from: The fields points radially out from the positive or north poles of long line. The s is the pole strength per unit length [emu/cm 2 ] [oe= emu/cm 3 ]

6 Demagnetization tensor N For ellipsoids, the demagnetization tensor is the same at all the points within the given body. The demagnetizing tensors for three cases are shown below: The flat plate has no demagnetization within its x-y plane but shows a 4  demagnetizing factor on magnetization components out of plane. A sphere shows a 4/3  factor in all directions. A long cylinder has no demagnetization along its axis, but shows 2  in the x and y directions of its cross sections. H S - the solenoid field

7

8

9 Electron spin Orbital momentum Magnetic moment of electron

10 Electron Spin The magnetic moment of spining electron is called the Bohr magneton 3d shells of Fe are unfilled and have uncompensated electron spin magnetic moments when Fe atoms condense to form a solid-state metallic crystal, the electronic distribution (density of states), changes. Whereas the isolated atom has 3d: 5+, 1-; 4s:1+, 1-, in the solid state the distribution becomes 3d: 4.8+, 2.6-; 4s: 0.3+,0.3-. Uncompensated spin magnetic moment of Fe is 2.2  B.

11 Electron spin

12 Exchange coupling The saturation of magnetization M S for body-centered cubic Fe crystal can be calculated if lattice constant a=2.86 Å and two iron atoms per unit cell.

Download ppt "Fundamentals of Magnetism T. Stobiecki. Definitions of magnetic fields Induction: External magnetic field: Magnetizationaverage magnetic moment of magnetic."

Similar presentations

Spin order in correlated electron systems

Spin order in correlated electron systems
We have looked at the magnetic field from a single loop of wire

We have looked at the magnetic field from a single loop of wire
Can be defines as: Phenomenon by which materials assert an attractive or repulsive force or influence on other materials Magnetic Materials includes -iron,

Can be defines as: Phenomenon by which materials assert an attractive or repulsive force or influence on other materials Magnetic Materials includes -iron,
Continuous Charge Distributions

Continuous Charge Distributions
Start EM Ch.5: Magnetostatics finish Modern Physics Ch.7: J=L+S Methods of Math. Physics, Thus. 24 Feb. 2011, E.J. Zita Magnetostatics: Lorentz Force and.

Start EM Ch.5: Magnetostatics finish Modern Physics Ch.7: J=L+S Methods of Math. Physics, Thus. 24 Feb. 2011, E.J. Zita Magnetostatics: Lorentz Force and.
Lecture 11 Magnetism of Matter: Maxwell’s Equations Chp

Lecture 11 Magnetism of Matter: Maxwell’s Equations Chp
c18cof01 Magnetic Properties Iron single crystal photomicrographs

c18cof01 Magnetic Properties Iron single crystal photomicrographs
Magnetism and Magnetic Materials DTU (10313) – 10 ECTS KU – 7.5 ECTS Sub-atomic – pm-nm Module 2 04/02/2001 Isolated magnetic moments.

Magnetism and Magnetic Materials DTU (10313) – 10 ECTS KU – 7.5 ECTS Sub-atomic – pm-nm Module 2 04/02/2001 Isolated magnetic moments.
Fundamentals of Magnetism T. Stobiecki, Katedra Elektroniki AGH 2 wykład 18.10.2004.

Fundamentals of Magnetism T. Stobiecki, Katedra Elektroniki AGH 2 wykład
Chapter 24 Gauss’s Law.

Chapter 24 Gauss’s Law.
1/18/07184 Lecture 71 PHY 184 Spring 2007 Lecture 7 Title: Using Gauss’ law.

1/18/07184 Lecture 71 PHY 184 Spring 2007 Lecture 7 Title: Using Gauss’ law.
MSE-630 Magnetism MSE 630 Fall, 2008.

MSE-630 Magnetism MSE 630 Fall, 2008.
Week 14: Magnetic Fields Announcements MatE 153, Dr. Gleixner 1.

Week 14: Magnetic Fields Announcements MatE 153, Dr. Gleixner 1.
Topics in Magnetism III. Hysteresis and Domains

Topics in Magnetism III. Hysteresis and Domains
Topics in Magnetism I. Definitions and Atomic Sources

Topics in Magnetism I. Definitions and Atomic Sources
Magnetoelectronics Wykłady dla doktorantów Politechniki Warszawskiej 5 styczeń 2005 Tomasz Stobiecki AGH Katedra Elektroniki.

Magnetoelectronics Wykłady dla doktorantów Politechniki Warszawskiej 5 styczeń 2005 Tomasz Stobiecki AGH Katedra Elektroniki.
Biot-Savart Law Moving charge produces a curly magnetic field

Biot-Savart Law Moving charge produces a curly magnetic field
Department of Electronics Nanoelectronics 11 Atsufumi Hirohata 12:00 Wednesday, 18/February/2015 (P/L 006)

Department of Electronics Nanoelectronics 11 Atsufumi Hirohata 12:00 Wednesday, 18/February/2015 (P/L 006)
MAGNETIC MATERIALS  Origin of Magnetism  Types of Magnetism  Hard and Soft Magnets Magnetic Materials – Fundamentals and Device Applications Nicola.

MAGNETIC MATERIALS  Origin of Magnetism  Types of Magnetism  Hard and Soft Magnets Magnetic Materials – Fundamentals and Device Applications Nicola.
From Chapter 23 – Coulomb’s Law

From Chapter 23 – Coulomb’s Law

Similar presentations

Ads by Google