Expert-level condensed matter physics knowledge. Use when working with crystal structure, band theory, semiconductors, superconductivity, magnetism, phase transitions, Fermi liquids, topological materials, or strongly correlated systems. Also use when the user mentions 'band gap', 'Fermi energy', 'semiconductor', 'superconductor', 'phonon', 'crystal lattice', 'Brillouin zone', 'Bloch theorem', 'Hall effect', 'magnetism', 'phase transition', or 'topological insulator'.
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Bravais lattices:
14 distinct lattice types in 3D (7 crystal systems)
R = n₁a₁ + n₂a₂ + n₃a₃ (lattice vectors)
Common structures:
Simple cubic (SC): 1 atom/cell
BCC (body-centered cubic): 2 atoms/cell (Na, Fe, W)
FCC (face-centered cubic): 4 atoms/cell (Cu, Al, Au, Ni)
HCP (hexagonal close packed): 2 atoms/cell (Mg, Ti, Zn)
Diamond cubic: 8 atoms/cell (Si, Ge, C)
NaCl structure: FCC with 2-atom basis
Reciprocal lattice:
G = m₁b₁ + m₂b₂ + m₃b₃
bᵢ·aⱼ = 2πδᵢⱼ
b₁ = 2π(a₂×a₃)/(a₁·a₂×a₃)
Brillouin zone:
First BZ = Wigner-Seitz cell of reciprocal lattice
All distinct k-vectors contained in first BZ
X-ray diffraction:
Bragg's law: 2d·sinθ = nλ
Structure factor: Sk = Σⱼ fⱼ exp(iG·rⱼ)
Systematic absences → determine crystal structure
Miller indices (hkl):
Planes with intercepts a/h, b/k, c/l
Spacing: d = a/√(h²+k²+l²) (cubic)
Drude model (classical):
σ = ne²τ/m (electrical conductivity)
τ = mean free time between collisions
Hall coefficient: RH = -1/ne
Sommerfeld model (quantum):
Electrons in box: ψk = (1/√V)exp(ik·r)
Energy: εk = ℏ²k²/2m
Fermi energy: EF = (ℏ²/2m)(3π²n)^(2/3)
Fermi wavevector: kF = (3π²n)^(1/3)
Fermi temperature: TF = EF/kB
Density of states:
g(ε) = (3n/2EF)(ε/EF)^(1/2) (3D)
g(EF) = 3n/2EF
Fermi-Dirac distribution:
f(ε) = 1/[exp((ε-μ)/kBT) + 1]
At T=0: f = 1 for ε < EF, f = 0 for ε > EF
Chemical potential μ ≈ EF at low T
Sommerfeld expansion:
Electronic heat capacity: Cv = (π²/3)kB²T·g(EF) = γT
γ = π²kB²g(EF)/3 (Sommerfeld coefficient)
Much smaller than classical Cv = 3nkB/2 ✓
Bloch theorem:
ψnk(r) = unk(r)exp(ik·r)
unk(r+R) = unk(r) (periodic part)
States labeled by band index n and k in BZ
Nearly free electron model:
Weak periodic potential V(r) = ΣG VG exp(iG·r)
Band gaps open at BZ boundaries
Gap size ≈ 2|VG| at zone boundary k = G/2
Tight binding model:
ψk = (1/√N) Σᵣ exp(ik·R) φ(r-R)
εk = ε₀ - t Σ_NN exp(ik·δ) (δ = nearest neighbor vectors)
1D: εk = ε₀ - 2t·cos(ka)
Bandwidth W = 4t (1D), larger in higher dimensions
Band classification:
Metal: partially filled band OR overlapping bands
Insulator: completely filled bands, large gap (Eg > 4eV)
Semiconductor: completely filled bands, small gap (Eg < 4eV)
Semimetal: tiny overlap of valence and conduction bands
Effective mass:
1/m* = (1/ℏ²) d²ε/dk²
Captures band curvature effect on dynamics
Can be negative (holes at top of band)
m* << m: light electrons (high mobility)
Intrinsic semiconductor:
n = p = nᵢ = √(NcNv) exp(-Eg/2kBT)
Nc = 2(2πmₑ*kBT/h²)^(3/2) (effective DOS)
Fermi level: μ = Eg/2 + (3/4)kBT·ln(mₕ*/mₑ*)
Doped semiconductors:
n-type (donor atoms, e.g. P in Si): excess electrons
n ≈ ND (donor concentration), p = nᵢ²/n
p-type (acceptor atoms, e.g. B in Si): excess holes
p ≈ NA, n = nᵢ²/p
Mass action law: np = nᵢ²
Carrier transport:
Drift: J = (neμₑ + peμₕ)E (σ = neμₑ + peμₕ)
Diffusion: J = eDₑ∇n - eDₕ∇p
Einstein relation: D/μ = kBT/e
p-n junction:
Built-in potential: Vbi = (kBT/e)ln(NAND/nᵢ²)
Depletion width: W = √(2ε₀εr·Vbi/e · (NA+ND)/(NAND))
I-V: I = I₀[exp(eV/kBT) - 1] (Shockley equation)
Semiconductor properties (Si at 300K):
Eg = 1.12 eV, nᵢ = 1.5×10¹⁰ cm⁻³
μₑ = 1400, μₕ = 450 cm²/Vs
ε = 11.7
1D monatomic chain:
ω(k) = 2√(K/m) |sin(ka/2)|
Acoustic branch: ω → 0 as k → 0
vg = dω/dk = a√(K/m)cos(ka/2)
1D diatomic chain:
Two atoms per unit cell → two branches
Acoustic: both atoms move same direction
Optical: atoms move in opposite directions
Gap at zone boundary: ω = √(2K/M±m)
Phonon dispersion in 3D:
N atoms/cell → 3N branches
3 acoustic + 3(N-1) optical branches
Debye model:
Linear dispersion: ωD = vsqD (Debye cutoff)
Cv = 9NkB(T/θD)³∫₀^(θD/T) x⁴eˣ/(eˣ-1)² dx
High T: Cv → 3NkB (Dulong-Petit)
Low T: Cv ∝ T³ (Debye T³ law)
θD = Debye temperature (characteristic)
Einstein model:
All phonons same frequency ωE
Cv = 3NkB(θE/T)² eθE/T/(eθE/T-1)²
Works well for optical modes
Thermal conductivity:
κ = (1/3)Cv·v·ℓ (kinetic theory)
ℓ = phonon mean free path
Umklapp scattering limits κ at high T
Diamagnetism:
χ < 0 (small, negative susceptibility)
Induced moment opposes applied field
Present in all materials (Lenz's law)
Superconductors: perfect diamagnets χ = -1
Paramagnetism:
χ > 0, small
Curie law: χ = C/T (isolated magnetic moments)
C = nμ₀μ²/3kB (Curie constant)
Pauli paramagnetism (metals): χ ∝ g(EF), T-independent
Ferromagnetism:
Spontaneous magnetization below TC (Curie temperature)
Weiss molecular field: Bmol = λM
Mean field theory: M = nμ·tanh(μ(B+λM)/kBT)
TC = nμ₀μ²λ/3kB
Above TC: Curie-Weiss: χ = C/(T-TC)
Antiferromagnetism:
Neighboring spins antiparallel
Neel temperature TN: transition to disorder
χ has maximum at TN
Ferrimagnetism:
Antiparallel but unequal moments → net magnetization
Example: magnetite Fe₃O₄
Ising model:
H = -J Σ_<ij> SᵢSⱼ - B Σᵢ Sᵢ
J > 0: ferromagnetic, J < 0: antiferromagnetic
1D: no phase transition at T > 0 (Ising 1925)
2D: TC = 2J/kB·ln(1+√2) (Onsager 1944)
3D: requires numerical methods
Discovery: Onnes 1911 (mercury, 4.2 K)
Meissner effect: perfect diamagnetism (B = 0 inside)
Critical temperature TC, critical field HC(T)
London equations:
∂J/∂t = (nse²/m)E
∇×J = -(nse²/m)B
London penetration depth: λL = √(m/μ₀nse²)
Magnetic field decays inside: B(x) = B₀exp(-x/λL)
BCS Theory (Bardeen, Cooper, Schrieffer 1957):
Cooper pairs: two electrons bound via phonon exchange
Binding energy gap: Δ = 2ℏωD exp(-1/N(0)V)
TC = 1.13 ℏωD/kB exp(-1/N(0)V)
Energy gap: 2Δ(0) = 3.52 kBTC (BCS universal ratio)
Coherence length: ξ = ℏvF/πΔ
Type I vs Type II:
κ = λL/ξ < 1/√2: Type I (complete Meissner, single HC)
κ > 1/√2: Type II (vortex phase, HC1 < H < HC2)
Josephson effect:
Current through insulating barrier: I = IC sin(φ)
DC Josephson: supercurrent with no voltage
AC Josephson: V = ℏ/2e · dφ/dt = hf/2e
SQUID: superconducting quantum interference device
High-temperature superconductors:
Cuprates (YBCO): TC ~ 90-130 K
Iron-based: TC ~ 55 K
MgB₂: TC = 39 K
Mechanism not fully understood (not BCS)
Record: LaH₁₀ at high pressure, TC ~ 250 K
Order parameter η:
η = 0 in disordered phase, η ≠ 0 in ordered phase
Magnetization (magnetic), density difference (liquid-gas)
Landau theory:
F = a₀ + a₂(T-TC)η² + a₄η⁴ + ...
a₄ > 0: second order transition
a₄ < 0: first order transition
Critical exponents:
M ∝ |T-TC|^β β ≈ 0.326 (3D Ising)
χ ∝ |T-TC|^(-γ) γ ≈ 1.237
Cv ∝ |T-TC|^(-α) α ≈ 0.110
ξ ∝ |T-TC|^(-ν) ν ≈ 0.630
Mean field: β=1/2, γ=1, α=0, ν=1/2
Scaling and universality:
Critical exponents depend only on:
- Dimensionality d
- Symmetry of order parameter
NOT on microscopic details!
Renormalization group (Wilson, Nobel 1982):
Systematic method to calculate critical exponents
Key idea: integrate out short-wavelength fluctuations
Fixed points → universality classes
Integer Quantum Hall Effect (IQHE):
2D electron gas in magnetic field
Hall conductance: σxy = ne²/h (n = integer)
Chern number: topological invariant
Robust against disorder!
Topological insulators:
Bulk insulating gap, but metallic surface states
Protected by time-reversal symmetry
Surface states: Dirac cone, spin-momentum locking
Examples: Bi₂Se₃, Bi₂Te₃, HgTe quantum wells
Topological invariants:
Z₂ invariant (time-reversal invariant systems)
Chern number (breaks time-reversal)
Calculated from Bloch wavefunctions in BZ
Weyl semimetals:
Linear crossing of two bands in 3D (Weyl points)
Topological charge (chirality) ±1
Fermi arc surface states connecting Weyl points
Examples: TaAs, WTe₂
Majorana fermions:
Particles that are their own antiparticles
Predicted in topological superconductors
Non-Abelian anyons — topological quantum computing
| Pitfall | Fix |
|---|---|
| Free electron model for semiconductors | Need band theory — effective mass matters |
| Confusing phonons and photons | Phonons: quantized lattice vibrations (not light) |
| Type I vs II superconductors | Determined by κ = λ/ξ ratio |
| Mean field always valid | Fluctuations crucial near TC, especially in low d |
| Band gap = energy gap | In superconductors energy gap is different concept |
| All metals are Fermi liquids | Strongly correlated systems (Mott insulators) break down |