All materials have magnetic properties.
These characteristic properties may be divided into five groups as
follows:
● diamagnetic
● paramagnetic
● ferromagnetic
● antiferromagnetic
● ferrimagnetic
Only ferromagnetic and ferrimagnetic
materials have properties which are useful in practical applications.
Ferromagnetic properties are confined almost entirely to iron, nickel
and cobalt and their alloys. The only exceptions are some alloys of
manganese and some of the rare earth elements.
Ferrimagnetism is the magnetism of the
mixed oxides of the ferromagnetic elements. These are variously
called ferrites and garnets. The basic ferrite is magnetite, or
Fe3O4, which can be written as FeO.Fe2O3. By substituting the FeO
with other divalent oxides, a wide range of compounds with useful
properties can be produced.
The main advantage of these materials
is that they have high electrical resistivity which minimizes eddy
currents when they are used at high frequencies. The important
parameters in magnetic materials can be defined as follows:
● permeability – this is the flux
density B per unit of magnetic field H. It is usual and more
convenient to quote the value of relative permeability μr, which is
B/μoH. A curve showing the variation of permeability with magnetic
field for a ferromagnetic material is given in Fig. 3.1.
This is derived from the initial
magnetization curve and it indicates that the permeability is a
variable which is dependent on the magnetic field. The two important
values are the initial permeability, which is the slope of the
magnetization curve at H = 0, and the maximum permeability,
corresponding to the knee of the magnetization curve.
● saturation – when sufficient
field is applied to a magnetic material it becomes saturated. Any
further increase in the field will not increase the magnetization and
any increase in the flux density will be due to the added field. The
saturation magnetization is Ms in amperes per metre and Js or Bs in
tesla.
● remanence, Br and coercivity, Hc –
these are the points on the hysteresis loop shown in Fig. 3.2 at
which the field H is zero and the flux density B is zero,
respectively. It is assumed that in passing round this loop, the
material has been saturated. If this is not the case, an inner loop
is traversed with lower values of remanence and coercivity.
Ferromagnetic and ferrimagnetic
materials have moderate to high permeabilities. The permeability
varies with the applied magnetic field, rising to a maximum at the
knee of the B–H curve and reducing to a low value at very high
fields.
These materials also exhibit magnetic
hysteresis, where the intensity of magnetization of the material
varies according to whether the field is being increased in a
positive sense or decreased in a negative sense, as shown in Fig.
3.2.
When the magnetization is cycled
continuously around a hysteresis loop, as for example when the
applied field arises from an alternating current, there is an energy
loss proportional to the area of the included loop.
This is the hysteresis loss, and it is
measured in joules per cubic metre. High hysteresis loss is
associated with permanent magnetic characteristics exhibited by
materials commonly termed hard magnetic materials, as these often
have hard mechanical properties.
Those materials with low hysteresis
loss are termed soft and are difficult to magnetize permanently.
Ferromagnetic or ferrimagnetic properties disappear reversibly if the
material is heated above the Curie temperature, at which point it
becomes paramagnetic, that is effectively non-magnetic.
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