What are ferromagnetic domains?
Ferromagnetic materials have areas with the same spin orientation (domains) that all together are non-magnetized. The boundaries where they meet are blurry, there, the electron’s spins gradually flip.
What is Diamagnetism?
All materials have a tendency to align the spin and angular momenta of their atoms against an external B-field (since N is attracted to S and vice versa). This is called Diamagnetism. The magnetic susceptibility resulting from Diamagnetism is negative
What is magnetic susceptibility?
How much a material magnetizes when it is put into an external field:
chi = M / H = \mu_0 * M / B
What is the difference between Landau diamagnetism and the magnetism of isotropic substances?
In isotropically bound substances, e.g. certain ionic lattices, the diamagnetic susceptibility is temperature independent.
In metals, the free electrons behave in a similar way, but we have to consider effective masses and density of states, leading to the Landau diamagnetism.
What is Paramagnetism?
When the material responds to an external magnetic field by aligning its inner dipoles with it instead of against it.
What is stronger, Paramagnetism or Diamagnetism?
Paramagnetism (if the material is paramagnetic). Diamagnetism is a phenomenon happening in all materials
What are the Hund’s rules?
To find the Ground state of an atom:
Spin is maximized
L (sum of m_L) is maximized under the condition of 1.
If the orbital (d, s, …) is more than half full, J=L+S, otherwise J=|L-S|
How can a Magnetization curve in Paramagnetism be described?
With a Brillouin function.
For low ratios B/T (room temp, weak magnets), the magnetization is approximately proportional to C/T with C being the Curie constant (Curie’s Law).
For high ratios B/T, the magnetization is approximately constant (saturation)
Why do elements in the 4f range of the Periodic system follow the prediction of Curie’s law whereas elements in the 3d range are deviating from it?
Because lattices in a crystal disturb the rotational invariance used to describe H-atom orbitals. This leads to irregularities in angular momenta.
For 4f electrons, this does not play a big role, since they are more inside of the atom and get shielded by the outer electrons.
What is Pauli Paramagnetism?
In a metal, spin up and down electrons will have different energies when a magnetic field is applied. So, the Density of state functions will shift. Since the Fermi energy needs to be constant over the whole system, some electrons will switch from one spin to the other, aligning with the field.
What is Ferromagnetism?
Materials that can spontaneously align their magnetic moments and keep this alignment even without a magnetic field
What is the Mean field approximation?
To approximate all dipoles around the dipole of interest in a ferromagnetic material as an effective field.
What is the Stoner or Band Ferromagnetism?
It works a little bit like Pauli Paramagnetism, but the Energy levels are not only shifted because of the external B-field, but because of an imbalance in the spin up and the spin down electrons. This leads to a self-enhancing shift of energies until all electrons are aligned
What is the Stoner criterium?
It tells whether a material is ferromagnetic. The Susceptibility of Stoner Ferromagnetism is like The Pauli Susceptibility, but divided by a Term 1-(I D(E_F)/(2n)) . If this term is bigger than one, spontaneous magnetization can happen. If it is smaller than one, the material is not ferromagnetic.
1-(I D(E_F)/(2n))
What is a Magnon and how is it’s dispersion relation?
A magnon is a spin orientation wave that is caused by short ranged interactions, it works a lot like phonons. Magnons happen for T higher than 0.
The disperion relation looks like a phonon dispersion relation.
What is the difference between Antiferromagnetism and Ferrimagnetism?
Both materials have two sublattices that align their spins opposing to each other. For Ferrimagnets, the two sublattices have different magnetic moments, leading to an overall magnetization. Antiferromagnets do not have an overall magnetization.
Where does the hysteresis curve of magnetization for ferromagnets come from?
When all spins are aligned in one direction, the changing magnetic field first needs to overcome the interaction energy of the particle spins. This is why the magnetization changes slowly at the beginning. Then, M is proportional to B as in paramagnets. And for high B fields, it will start to approach the saturation magnetization.
What is the Barkhausen effect?
The Barkhausen effect describes sudden noisy jumps in the magnetization curve of ferromagnets due to the sudden alignment of ferromagnetic domains.
What is Superparamagnetism?
Below a certain sample size, ferromagnetic materials loose their ability to maintain their magnetization after the field is turned off.
This is due to the fact that there are less other particles to interact with, causing the energy barrier for demagnetization to be very low (lower than thermal energy).
Thus, below the curie and above the “blocking temperature”, these particles will be thermically demagnetized (magnons). The blocking temperature value is dependent on the particle size.
The energy barrier can be heightened by using a magnetically anisotrop material.
Where does Superparamagnetism play a role in application?
It physically limits the storage density of magnetic storage devices
The relaxation times of superparamagnetic beads can be used for contrast in MRIs
How does the magnetic susceptibility of Antiferromagnets behave?
For Temperatures higher than the Neel Temperature, it behaves like a paramagnet and is proportional to the inverse of T.
Below the Neel Temperature, the susceptibility is dependend on the direction of the field. If it is perpendicular to the direction of spontaneous magnetization, it stays constant. Otherwise, it falls with shrinking T.
What is the difference between antiferromagnetic magnons and ferromagnetic magnons?
Ferromagnetic magnons go with
E(k)=4JS(1-cos(ka))
Whereas Antiferromagnetic magnons go with
E(k)=-4JS|sin(ka)|
What are superstructure peaks?
In antiferromagnetic materials, the Brillouin zone size depends on the magnetization.
If there is no magnetization at all (higher T), it is bigger, whereas if the sublattices are magnetized in different directions, it is half as big as before.
This causes new “superstructural” peaks in crystal x-ray diffraction experiments.
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