1961
DOI: 10.1103/physrev.122.475
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Infrared Cyclotron Resonance in InSb

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Cited by 166 publications
(37 citation statements)
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“…This expansion was inadequate for InSb because of its stronger non-parabolicity which is due to a considerably weaker energy gap. Assuming that the energy can be written Palik et al [27]. The data show an important increase of the effective mass with doping, which has been studied in terms on the non-parabolicity of by Cardona [lo] and Korenblit et al [36].…”
Section: Ezperimental Datamentioning
confidence: 98%
“…This expansion was inadequate for InSb because of its stronger non-parabolicity which is due to a considerably weaker energy gap. Assuming that the energy can be written Palik et al [27]. The data show an important increase of the effective mass with doping, which has been studied in terms on the non-parabolicity of by Cardona [lo] and Korenblit et al [36].…”
Section: Ezperimental Datamentioning
confidence: 98%
“…2a and b. In order to model the cyclotron resonance transitions, we employ a formula originally used by Palik et al [10] to describe the cyclotron resonance transition energies ( y± = 2Ε± /Εg) in bulk InAs up to 10 Τ In this approach the three main variables are the band gap (Eg) and the band edge mass (m^) and g-value (go) which appear in the dimensionless parameters and x = ħω 0 /Εg and δ = (g*0m*0/m). One problem in fitting the data is to determine the value of the effective band gap to use at room temperature as only the dilational component of the reduction in Eg with increasing temperature will change the effective mass.…”
Section: Experiments With Bulk ιNas1-x Sbx Alloysmentioning
confidence: 99%
“…The response due to polar lattice vibrations must be further taken into account, and which causes the so-called longitudinal plasmon phonon (LPP) modes. Detailed analysis of their magnetooptic response reveals further fine structure due to coupling with the cyclotron motion and interface polariton excitations [26,41,74,75]. …”
Section: Complex Anisotropic Mediums: Sculptured Thin Filmsmentioning
confidence: 99%