Light Scattering Spectroscopy

Light Scattering Spectroscopy
References : H. Ibach and H. Luth, “Solid-State Physics” (Springer-Verlag, 1990) P.Y. Yu and M. Cardona, “Fundamentals of Semiconductors” (Springer-Verlag, 1996) J.S. Blakemore, “Solid State Physics” (Cambridge University Press, 1985) J.I. Pankove, “Optical Processes in Semiconductors” (Dover Publications, Inc., 1971)

Inelastic scattering of light can result in vibrational excitations of the atoms Longitudinal waves in 1-D monatomic crystal (linear chain of atoms) : a r-2 r-1 r r+1 r+2 +x

Hooke’s law for atom r : Fr = -m(xr – xr+1) – m(xr – xr-1) = m (xr+1 + xr-1 – 2xr) (Eq. 1) Longitudinal displacements : xr = A exp i(kra – wt) Fr = m d2xr/dt2 = - m w2xr (Eq. 2) a r-2 r-1 r r+1 r+2 +x

Equating Eq. 1 & 2 : w2 = (m/m) (2 – xr+1/xr – xr-1/xr) Substituting in Eq. 2 : w2 = (m/m) (2 – eika – e-ika) = (4m/m) sin2(ka/2) w = ± 2(m/m)½ sin (ka/2) (dispersion relationship)

w = ± 2(m/m)½ sin (ka/2) (dispersion relationship) From Blakemore, Fig. 2-3, p. 94

w = ± 2(m/m)½ sin (ka/2) (dispersion relationship) Smallest wavelength is 2a Largest k = ± p/a a r-2 r-1 r r+1 r+2 +x

Can describe dispersion curve entirely within k = 0 to k = G = p/a From Blakemore, Fig. 2-3, p. 94

For small k, w = [ (m/m)½a ] k Speed of sound in the material From Blakemore, Fig. 2-3, p. 94

Must also include transverse vibrations Atomic spacing, a, will vary for different directions in the scrystal; dispersion curves are plotted for different directions Deviations from simple model occur due to forces from remote neighbors from Blakemore, Fig. 204, p. 96

Longitudinal waves in 1-D diatomic crystal : a r-2 r-1 r r+1 r+2 m M

Longitudinal displacements : xr = A exp i(kra – wt) xr+1 = B exp i[k(r+1)a – wt ] -m w2 xr = m (xr+1 + xr-1 – 2xr) -M w2 xr+1 = m (xr+2 + xr – 2xr+1) a r-2 r-1 r r+1 r+2 m M

Substituting and rearranging as before : A(2m-mw2)=2mBcoska B(2m-Mw2)=2mAcoska Combining terms to eliminate A and B gives: w2 = m(m-1 + M-1) ± m [ (m-1 + M-1) – (4sin2ka)/mM ]½

w2 = m(m-1 + M-1) ± m [ (m-1 + M-1) – (4sin2ka)/mM ]½ From Blakemore, Fig. 2-10, p. 107

2 curves separated by gap Lower curve Acoustic branch Similar to previous monatomic chain Upper curve Optical branch From Blakemore, Fig. 2-10, p. 107

Optical branch Near k = 0 atoms move in opposite directions Ionic bonding has a dipole moment Optical phonons can be excited optically From Blakemore, Fig. 2-11, p. 109

3-D Polyatomic Crystals : Any 3-D crystal can be described by a unit cell and a basis The basis are the atoms and their orientation with respect to each lattice point There are 14 possible 3-D unit cells (Bravais lattices)

From Blakemore, Fig. 1-21, p. 36

From Blakemore, Table 1-6, p. 37

3-D Polyatomic Crystals : Twice as many transverse compared to optical branches A basis of p atoms has 3p branches (3p vibrational modes) basis = p atoms acoustic optical 1 longitudinal (LA) 2 transverse (TA) (p-1) longitudinal (LO) 2(p-1) transverse (TO)

3-D Polyatomic Crystals : e.g., C, Si diamond structure = fcc unit cell + basis of p = 2 atoms basis = 2 atoms acoustic optical 1 longitudinal (LA) 2 transverse (TA) 1 longitudinal (LO) 2 transverse (TO)

3-D Polyatomic Crystals : In Si and C, both transverse branches are degenerate along [111] and [100] directions due to symmetry From Blakemore, Fig. 2-13, p. 112

Reflected light (Rayleigh scattering) Ei = ħwi |ps| = |pi| Incident light Ei = ħwi pi = ħki Inelastic scattering of light Es = ħws ps = ħks Phonon Ep = ħw(k) pp = ħk Frequency shifts of scattered light are characteristic of the material

Inelastic Light Scattering
Conservation of energy and momentum: Phonon absorption: Es – Ei = + ħw(k) ks – ki = + k Phonon emission: Es – Ei = - ħw(k) ks – ki = - k

Maximum phonon wavevector excited using visible light is: |k| = |ki – ks| = 2(2p)/l ~ 2 x 10-3 Å-1 |G| = p/a ~ few Å-1 |k| << |G|

|k| << |G| for visible light Can only excite phonons near k ~ 0 From Pankove, Fig , p. 273

Must use neutrons with Ei ~ 0.1 – 1 eV for phonon spectroscopy Brockhouse and Shull, Nobel prize in 1994 for inelastic neutron scattering work performed in 1950’s

Raman Scattering Nobel prize in 1930 Inelastic scattering of light from optical phonons E(k~0) ~ constant (LO, TO) From Blakemore, Fig. 2-13, p. 112

Stokes shift: phonon is created; light loses energy Anti-Stokes shift: phonon is destroyed; light gains energy From Yu & Cardona, Fig. 7.21, p. 375

Raman scattered light intensity ~ 104 – 108 times weaker than elastically scattered light Need high intensity light source (laser) Sensitive detector with low background noise (cooled photodiode, PMT)

Frequency difference between Raman signal and laser light ~ 1% of laser frequency Need good spectral resolving power, R = l / Dl > 104 Need high stray light rejection ratio (notch filter to block laser light, 2 or more spectrometers in series = double monochromator)

double monochromator PMT sample laser

Raman Spectroscopy Can detect stress
Can determine composition and crystal structure Can detect stress From Schroder, Fig. 9.33, p. 632

Raman Spectroscopy Surface Enhanced Raman Scattering (SERS)
Coherent anti-Stokes Raman Scattering (CARS)

Brillouin Scattering Inelastic scattering of light with acoustical phonons A continuum of k values exist → a continuum of Stokes and anti-Stokes components From Pankove, Fig , p. 276

Frequency shifts are a few cm-1 Much smaller than Raman shifts (few 100 cm-1) From Yu & Cardona, Fig. 7.30, p. 389

Use Fabry-Perot interferometer rather than grating spectrometer From Yu & Cardona, Fig. 7.29, p. 388

Light Scattering Spectroscopy

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