Carrier concentration and lattice absorption in bulk and epitaxial silicon carbide determined using infrared ellipsometry

Abstract: Wetteroth, T.; Wilson, S. R.; and Powell, Adrian R., "Carrier concentration and lattice absorption in bulk and epitaxial silicon carbide determined using infrared ellipsometry" (1999 Carrier concentration and lattice absorption in bulk and epitaxial silicon carbide determined using infrared ellipsometry We have measured the dielectric function of bulk nitrogen-doped 4H and 6H SiC substrates from 700 to 4000 cm Ϫ1 using Fourier-transform infrared spectroscopic ellipsometry. Photon absorption by transverse optic… Show more

“…At the Fröhlich resonance with Re(ε) = -2, ωdRe(ε)/dω∼10-30 for both noble metals and doped semiconductors (with values ≈20 for Ag [90]), the permittivity dispersion is enhanced in SPhP materials. For 4H-SiC at λ = 10.7 μm, ωdRe(ε)/dω≈60 [57], while for GaAs at λ = 34.6 μm, ωdRe(ε)/dω≈150 [59]. From Eqs.…”

“…2)] as a function of Re(ε) is shown for the SPhP materials 4H-SiC [57] and GaAs [59], and the plasmonic materials n-type InGaAs [29], and silver [89,90] in Figure 4A. A more comprehensive comparison of a wide range of plasmonic metals (red circles), metal alloys (pink hexagons), doped semiconductors (blue stars) and SPhP materials (green squares) are provided in Figure 4B.…”

“…(2.2). The spectral dependence of the permittivity calculated for a 4H-SiC epitaxial layer from infrared spectroscopic ellipsometry results reported by Tiwald et al [57] are presented for the entire Reststrahlen band in Figure 3A, and a magnified view covering the range of 1 ≥ Re(ε) ≥ -20 is provided in Figure 3C. For comparison, Figure 3B and D give the corresponding plots for the lowest-loss plasmonic material, silver, using optical constants from both Palik's compendium (solid lines) [89] and Johnson and Christie (dashed lines) [90].…”

“…The application of Eq. (3.2) gives maximum Q values > 600 using the optical constants reported by Tiwald et al [57], and 2)] for 4H-SiC (green trace) [57] and GaAs (blue trace) [59] SPhP and n-type In 0.3 Ga 0.7 As (red trace) [29] and Ag [using optical constants from Palik (solid gray trace) [89] and Johnson and Christy (dashed light gray trace) [90]] SPP localized resonators as a function of Re(ε). (B) Comparison of Q for a spherical particle in air for all SPP and SPhP materials listed in Tables 1 and 2, respectively.…”

“…SPhPs are the result of polar optical phonons interacting with long-wavelength incident fields from the mid-IR (e.g., hexagonal BN [52][53][54][55] and SiC [20,23,56,57]) to < 10 THz (e.g., GaAs [58,59], InP [60] and CaF 2 [61]), creating a surface excitation mediated by the atomic vibrations. Such SPhP modes can be stimulated in polar dielectric crystals between the longitudinal (LO) and transverse optic (TO) phonon frequencies, with this spectral range referred to as the "Reststrahlen" band [60,62,63].…”

Low-loss, infrared and terahertz nanophotonics using surface phonon polaritons

“…At the Fröhlich resonance with Re(ε) = -2, ωdRe(ε)/dω∼10-30 for both noble metals and doped semiconductors (with values ≈20 for Ag [90]), the permittivity dispersion is enhanced in SPhP materials. For 4H-SiC at λ = 10.7 μm, ωdRe(ε)/dω≈60 [57], while for GaAs at λ = 34.6 μm, ωdRe(ε)/dω≈150 [59]. From Eqs.…”

“…2)] as a function of Re(ε) is shown for the SPhP materials 4H-SiC [57] and GaAs [59], and the plasmonic materials n-type InGaAs [29], and silver [89,90] in Figure 4A. A more comprehensive comparison of a wide range of plasmonic metals (red circles), metal alloys (pink hexagons), doped semiconductors (blue stars) and SPhP materials (green squares) are provided in Figure 4B.…”

“…(2.2). The spectral dependence of the permittivity calculated for a 4H-SiC epitaxial layer from infrared spectroscopic ellipsometry results reported by Tiwald et al [57] are presented for the entire Reststrahlen band in Figure 3A, and a magnified view covering the range of 1 ≥ Re(ε) ≥ -20 is provided in Figure 3C. For comparison, Figure 3B and D give the corresponding plots for the lowest-loss plasmonic material, silver, using optical constants from both Palik's compendium (solid lines) [89] and Johnson and Christie (dashed lines) [90].…”

“…The application of Eq. (3.2) gives maximum Q values > 600 using the optical constants reported by Tiwald et al [57], and 2)] for 4H-SiC (green trace) [57] and GaAs (blue trace) [59] SPhP and n-type In 0.3 Ga 0.7 As (red trace) [29] and Ag [using optical constants from Palik (solid gray trace) [89] and Johnson and Christy (dashed light gray trace) [90]] SPP localized resonators as a function of Re(ε). (B) Comparison of Q for a spherical particle in air for all SPP and SPhP materials listed in Tables 1 and 2, respectively.…”

“…SPhPs are the result of polar optical phonons interacting with long-wavelength incident fields from the mid-IR (e.g., hexagonal BN [52][53][54][55] and SiC [20,23,56,57]) to < 10 THz (e.g., GaAs [58,59], InP [60] and CaF 2 [61]), creating a surface excitation mediated by the atomic vibrations. Such SPhP modes can be stimulated in polar dielectric crystals between the longitudinal (LO) and transverse optic (TO) phonon frequencies, with this spectral range referred to as the "Reststrahlen" band [60,62,63].…”

Low-loss, infrared and terahertz nanophotonics using surface phonon polaritons

Dielectric Function of Polycrystalline SiC from 190 nm to 15 ?m

Infrared Spectroscopic Ellipsometry