1. Presentation File: Additional materials
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12Aug2011
CMDAYS 2011 Aravamudhan

2. HOMOGENEOUS Magnetic Field
Magnetic Field representation by Lines of Force
Magnetic Field Vector
Vector map representation of Homogeneous magnetic Field. The scales should be so chosen that the magnitude of the individual Vectors in the map above, is equal to the Magnitude of the Vector in the line Vector representation. The individual vector magnitude should not be multiplied by the number of such vectors to equal the total magnetic field strength
An inhomogeneous magnetic field can be more conveniently represented by the Vector Maps of mathematics
A HOMOGENEOUS FIELD can be adequately represented by a Line VECTOR, but inhomogeneous field is represented well by the VECTOR MAP. See in the next slide illustrations of various distribution functions in Vector Maps
12Aug2011
CMDAYS 2011 Aravamudhan

3. Magnetization can be described also by Vector Maps and these Vector maps may not be called Vector Fields
The question framed as the title of the abstract can be reframed as whether, the Vectors constituting the Vector maps represent interacting Moments?
The question of interacting vectors of the Vector map may still be confronting, if the total magnetization vector magnitude is divided by the number of vector elements in the so that the total magnetization as the resultant of the vector elements
12Aug2011
CMDAYS 2011 Aravamudhan

4. The induced field calculations at a point
Line defined by Polar angle θ / direction of radial vector
Polar angle intervals Δθ are half the values of the corresponding intervals on the left.
Specifying the position coordinates for the plot of Vector map: described in next slide
The vector elements represent moments and not a field S N
The Vector Map representation for the divided magnetic moments and their distribution as per the criterion stipulated for the improved validity of point dipole approximation enabling the discrete summation to replace the integrals.
The induced field calculations at a point
16 Aug 2011
S.Aravamudhan CMDAYS2011

5. Volume of the sphere at distance ‘R’ is (4/3)π r3 = Vs with r = C(a constant) x R
Calculation of induced fields:
Ri+1 = Ri + ri + ri+1
With “C= Ri / ri, i=1, n”
For a sphere of radius =0.25 units, and the polar angle changes at intervals of 2 .5˚
There will be 144 intervals. Circumference= 2π/ so that the diameter of each sphere on the circumference = ; radius =
C = R/r = 0.25 / = [ / ] =
Log ( ) = (r/R) 3= e-5 =
Ri+1 = Ri ● (C+1) / (C-1)
For a predetermined polar angular co-ordinates (θ,Φ), the distance along the radial vector Ri+1 is calculated. Thus every vector in the Vector map can be specified by the vector magnitude |μi,θ,Φ| (which is proportional to the Volume of the sphere with radius ri,θ,Φ ) , position coordinates (ri,θ,Φ ,θ,Φ)
16 Aug 2011
S.Aravamudhan CMDAYS2011

6. |μi | = (4/3) π ri 3 · χv · |H|
with (ri )K where subscript K specifies a (θ,Φ ) angular polar coordinate,
The set of magnetic moments are mapped onto a Vector space with the Polar Coordinate space:
This Vector Map is more complicated version than the examples of Vector maps displayed in slide-2. This magnetic moment map should in turn return the magnetized specimen shape accounting for the entire material content of the magnetized material, with appropriately filling the Voids between spheres by (drawing) describing a cubical volume enclosing the sphere around every sphere
In place of each of the spherical element draw a Vector of appropriate magnitude ! That gives the Vector map of the Moments distribution
16 Aug 2011
S.Aravamudhan CMDAYS2011