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4. Phonons Crystal Vibrations

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1 4. Phonons Crystal Vibrations
Vibrations of Crystals with Monatomic Basis Two Atoms per Primitive Basis Quantization of Elastic Waves Phonon Momentum Inelastic Scattering by Phonons

2 Harmonic approximation: quadratic hamiltonian : elementary excitations
Electrons, polarons & excitons are quasi-particles

3 Vibrations of Crystals with Monatomic Basis
First Brillouin Zone Group Velocity Long Wavelength Limit Derivation of Force Constants from Experiment

4 Entire plane of atoms moving in phase → 1-D problem
Force on sth plane = (only neighboring planes interact ) Equation of motion: Dispersion relation

5 Propagation along high symmetry directions → 1-D problem
E.g. , [100], [110], [111] in sc lattice. longitudinal wave transverse wave

6 First Brillouin Zone → Only K  1st BZ is physically significant.
K at zone boundary gives standing wave.

7 Group Velocity Group velocity: 1-D: vG = 0 at zone boundaries

8 Derivation of Force Constants from Experiment
If planes up to the pth n.n. interact, Force on sth plane = If ωK is known, Cq can be obtained as follows: Prob 4.4

9 Two Atoms per Primitive Basis

10 Ka → 0: Gap Ka → π: (M1 >M2 ) Transverse case: TO branch, Ka → 0: TA branch, Ka → 0:

11 p atoms in primitive cell → d p branches of dispersion.
d = 3 → 3 acoustical : 1 LA + 2 TA (3p –3) optical: (p–1) LO + 2(p–1) TO E.g., Ge or KBr: p = 2 → 1 LA + 2 TA + 1 LO + 2 TO branches Ge KBr Number of allowed K in 1st BZ = N

12 Quantization of Elastic Waves
Quantization of harmonic oscillator of angular frequency ω → Classical standing wave: Virial theorem: For a power-law potential V ~ xp For a harmonic oscillator, p = 2,

13 Phonon Momentum Phonon DOFs involve relative coordinates
→ phonons do not carry physical linear momenta ( except for K = G modes ) Reminder: K = G  K = 0 when restricted to 1st BZ . Proof: See 7th ed. Scattering of a phonon with other particles behaves as if it has momentum  K E.g., elastic scattering of X-ray: G = reciprocal lattice vector ( whole crystal recoil with momentum  G / Bragg reflection) Inelastic scattering with a phonon created: Normal Process: G = 0. Umklapp Process: G  0. Inelastic scattering with a phonon absorbed:

14 Inelastic Scattering by Phonons
Neutron scattering: Conservation of momentum: Conservation of energy:

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