Prof. Masatsugu Sei Suzuki
Department of Physics, SUNY-Binghamton


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Lecture Notes:
General Physics
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Method of Theoretical Physics
Modern Physics
Solid State Physics
Quantum Mechanics - Graduate course
Quantum Mechanics I
Quantum Mechanics II
Senior Laboratory
Statistical Thermodynamics
 


Lecture Notes of Solid State Physics

  0 REFERENCES of Solid State Physics
  1    Introduction
  2    Crystal Structures
  3    Crystal bonding
  4    Reciprocal lattice
  5.1 x-ray diffraction
  5.2 Topics of x-ray diffraction
  5.3 x-ray diffraction problems and solutions
  5-4 Simulation of x-ray theta-two theta scattering.nb (Mathematica)
  6    Electron diffraction of 2D system
  7.1 Phonon I
  7.2 Phonon-II Thermal properties
  7.3 Heat capacity of 1D, 2D and 3D phonon
  7.4 Thermal conductivity of insulators
  7.5 Phonon statistics
  8    Neutron scattering
  9.1 Free electron Fermi gas model
  9.2 Density of states
  9.3 Density of state for metal superlattice
10.1 Fermi Dirac statistics
10.2 Fermi function
10.3 Fermi energy of fermions
10.4 Sommerfeld formula
11    Fermi liquid theory.pdf
12    White dwarf and neutron star
13.1 Electrical conductivity in metals
13-1S Conductivity in metals-Drude-Sommerfeld-Kubo
13.2 Thermal conductivity of metals
13.3 Universal constant for Thermal conductivity
13.4 Thermoelectric power
13.5 Magnetoresistance
14.1 Boltzmann Transport equation
14.2 Boltzmann transport II
15.1 Bloch electron in a periodic potential
15.2 Bloch theorem I
15.3 Bloch thorem and energy band II
15.4 Kronig Penney model
15.5 Nearly free electron perturbation
15.6 Cohesive energy in metals Wigner-Seitz method
16.1 Brillouin zone of rectangle lattice
16.2 Brillouin zone of 3D systems
17    Empty lattice approximation
18.1 Band structure
18.2 Fermi surface of Cu-open orbits
19    Harrison Construction of Fermi surface
20.1 Tight binding approximation
20.2 Mott insulator and Hubbard model

 		 21    Dynamics of Bloch electrons
22    de Haas van Alphen effect
23    Shoenberg effect in dHvA
24    Azbel-Kaner cyclotron resonance
25.1 Superconductivity
25.2 Ginzburg Landau equation
25.3 Josephson effect
25.4 Josephson junction and DC SQUID
26    Quantum Hall effect
27    Charge density wave
28    Fundamental property of magnetism
29.1 Diamagnetism and paramagnetism
29.2 The use of cgs units in magnetism
29.3 Langevin function
30.1 Spin one-half in magnetic field
30.2 Pauli paramagnetism
31.1 Mean-field theory
31.2 Stoner model
32    Crystal field and spin Hamiltonian
33    Superexchange interaction
34    Magnons of ferromagnetism
35    AC magnetic susceptibility
36    Magnetic neutron scattering
37    Nuclear magnetic resonance
38    Antiferromagnet in the field
39    Spin echo NMR
40    Hyperfine interaction
41    Mössbauer effect
42    Anderson localization
43    Kondo effect
44    Landauer formula in nanostructures
45    Rashba effect in the 2D system
46    Dirac electron in graphene
47    Wigner-Eckart Theorem for solid state physics


 

 

Revised: September 12, 2019