Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Straight-forward derivation of Kittel Eq. 9.37 It is possible to derive
Document related concepts
Maxwell's equations wikipedia , lookup
Introduction to gauge theory wikipedia , lookup
Time in physics wikipedia , lookup
History of quantum field theory wikipedia , lookup
Magnetic field wikipedia , lookup
Electromagnetism wikipedia , lookup
Neutron magnetic moment wikipedia , lookup
Field (physics) wikipedia , lookup
Lorentz force wikipedia , lookup
Magnetic monopole wikipedia , lookup
Superconductivity wikipedia , lookup
AharonovβBohm effect wikipedia , lookup
Transcript
Straight-forward derivation of Kittel Eq. 9.37 It is possible to derive this without reference to the vector potential and Bohr-Sommerfeld quantization, if we assume that the cross-section of the Fermi surface is circular. First, assume a two-dimensional electron gas in the x-y plane with a magnetic field in the zdirection. Then, as discussed in class, the electron energy is 1 1 βππ΅ πΈπ = (π + ) βππ = (π + ) . 2 2 π 1 The allowed states in k-space now fall on a series of circles with radii π = β β2ππΈ (see Fig. 24). As the magnetic field increases, these circles increase in radius. As a given circle βpopsβ through the Fermi energy, the states contained on that circle go from full to empty. We are interested in those magnetic fields π΅π for which πΈπ is equal to the Fermi energy: 1 βππ΅π β2 ππΉ2 β2 π (π + ) = = , 2 π 2π 2ππ where π = πππΉ2 is the area of the Fermi circle. In 3D, this would be the cross-sectional area of the Fermi surface. Rearrange this expression as follows: βπ 1 β . 2πππ΅π 2 Evaluating for π and π + 1 and taking the difference: π= βπ 1 1 ( β ), 2ππ π΅π+1 π΅π 1 so that any quantity that depends on field will be periodic in π΅ with period 1 2ππ Ξ( ) = . π΅ βπ 1= Note that this proof is not limited to 2D. If we go to 3D, we can take the z-axis to be the magnetic field direction and then 1 β2 ππ§2 πΈπ = (π + ) βππ + . 2 2π In other words, motion along the magnetic field direction is described by planes waves (or Bloch waves), which are not modified by the magnetic field. The rest of the argument proceeds as above, where π is the cross-section in the x-y plane. I admit that it is less obvious what to do in the general case where the Fermi surface no longer has a circular cross-section. The Bohr-Sommerfeld rule (Eq. 26) allows one to generalize the above results. The key point is that if the magnetic field is large enough and the sample clean enough, then just about any electronic property that depends on magnetic field will oscillate with a period determined by the extremal cross-sectional area of the Fermi surface. If you are willing to wade through the quantum mechanics and are looking for a rigorous proof, I recommend Ziman, Theory of Solids, pp. 313 β 324. He discusses quite clearly why only the extremal orbits need to be considered. I addressed this using pictures in class, but of course it can be proven.
