Magnetic Materials: Linear, Paramagnetic, Diamagnetic, and Ferromagnetic Properties - Prof, Study notes of Physics

Download Magnetic Materials: Linear, Paramagnetic, Diamagnetic, and Ferromagnetic Properties - Prof and more Study notes Physics in PDF only on Docsity! PHY481 - Lecture 30 Chapter 9 of PS, Sections 7.2.3, 7.2.4 of Griffiths A. Linear magnetic materials Linear magnetic materials are characterized by a linear relation between the magnetiza- tion and the magnetic field intensity, ~M = χm ~H, which is similar to the definition of linear dielectrics, ~P = 0χe ~E but not completely analogous. We also have, ~B = µ0 ~H + µ0 ~M = µ0(1 + χm) ~H = µ ~H (1) which is analogous to ~D =  ~E in dielectrics. µ is the permeability. This should not be confused with the magnetic moment for a current ring, which is also sometimes called ~µ. This is horrible notation, but it is entrenched in the area. We shall have to live with it. Most of the time I use ~m for the magnetic moment and ~M for the magnetization. B. Paramagnets, linear materials with χm > 0 Paramagnets do not exhibit spontaneous magnetic order, nevertheless they can have large magnetic susceptibilities. The magnetic moment of paramagnetic materials tries to align in the direction of the applied magnetic field. Actually all materials will magnetically order at sufficiently low temperatures, but when the ordering temperature is very low, materials are called paramagnetic. The susceptibility of paramagnetic materials obeys the Curie Law, χm = µ0C T (2) Paramagnetic materials are attracted to magnets. C. Diamagnets, linear materials with −1 < χm < 0 If elementary particles did not have an intrinsic magnetic moment, then all materials would be diamagnetic. That is, the magnetic moment of materials would be opposite the direction of the applied field. This is due to Lenz’s law. Superconductors are the best diamagnets, but many pure normal conductors are too (e.g. Cu...). At low enough values, magnetic fields are completely excluded from the interior of a superconductors. The phase in which this occurs is called the Meissner phase of a superconductor. From the expression, ~B = µ0(1 + χm) ~H (3) 1 it is evident that in order for flux to be completely expelled so that ~B = 0 inside the superconductor, we must have, χm = −1. A measurement of χm is one of the first measurements that people do to determine if a material is in the superconducting state. Diamagnetic materials are repelled from magnets. This enables the possibility of magnetic levitation. Since superconductors are the best diamagnets, they are the primary candidates for possible magnetic levitation applications. D. Ferromagnets, non-linear magnetic materials, hysteresis In ferromagnetic materials, the magnetic moments of the atoms in the material seek to align in the same direction. Examples are Fe and Permalloy (55% Fe, 45% Ni). It is actually quite difficult to find good ferromagnetic materials. There is a continuing search for ferromagnetic materials which have large local magnetic moments. A group at GM research in Detroit made a major breakthrough in this area about a decade ago. They helped develop the Niodymium, Iron, Boron magnets. The production of these magnets is now a multibillion dollar industry. Calculation of the fields around magnetics is carried out in a similar manner to the fixed magnetization case discussed above, e.g. for a uniformly magnetized sphere. A more general calculation uses a non-linear consitutive law. Sometimes ferromagnets are treated as a linear dielectric with a large positive value of χm - this is not completely correct, but it gives an indication of the expected behavior. Ferromagnetic materials are very important in technology. For example the hard drives in most computers are made using small domains on ferromagnetic materials. A small sensor (or read head) scans the surface of the hard drive. On the hard drive surface are small domains of ferromagnetic material. These domains are oriented in the plane of the surface and they have a prefered direction. The read head measures a resistivity which is sensitive to the local magnetic field. The technology of magnetic storage (e.g. hard drives) relies on a particular property of ferromagnetic materials. This property is called hysteresis. Hysteresis is a property which occurs when a magnetic field is applied to a ferromagnet which is below its Curie temperature. In order to describe hysteresis we must describe the way in which we vary the temperature and the magnetic field. Let us start at high temperatures and quench to a temperature well below the Curie temperature. The magnetic material is frozen in a domain structure by this process. Now we apply a positive external field. The domains now begin to align with 2