2009
DOI: 10.1103/physrevb.79.193307
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Temperature-dependent electron Landégfactor and the interband matrix element of GaAs

Abstract: Very high precision measurements of the electron Landé g factor in GaAs are presented using spin-quantum beat spectroscopy at low excitation densities and temperatures ranging from 2.6 to 300 K. In colligation with available data for the temperature-dependent effective mass temperature dependence of the interband matrix element within a common five-level k · p theory can model both parameters consistently. A strong decrease in the interband matrix element with increasing temperature consistently closes a long … Show more

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Cited by 52 publications
(40 citation statements)
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“…The negative sign is inferred from the theoretical model in which band-gap dependent corrections of the g-factor are subtracted from a positive value of 2 [14]. we observe a small increase of the negative g-factor towards zero, which is in agreement with observations in GaAs that were explained by a temperature dependence of the dipole matrix elements between the conduction and valence bands [16]. The spin decay time τ monotonically increases if T is lowered, reaching more than 1 ns at 10 K. Figure 2(c) shows the corresponding decay rate 1/τ .…”
supporting
confidence: 90%
“…The negative sign is inferred from the theoretical model in which band-gap dependent corrections of the g-factor are subtracted from a positive value of 2 [14]. we observe a small increase of the negative g-factor towards zero, which is in agreement with observations in GaAs that were explained by a temperature dependence of the dipole matrix elements between the conduction and valence bands [16]. The spin decay time τ monotonically increases if T is lowered, reaching more than 1 ns at 10 K. Figure 2(c) shows the corresponding decay rate 1/τ .…”
supporting
confidence: 90%
“…The negative sign is assigned from the relation g à ¼ À0:48 þ E F . We determine the factor which reflects the energy dependence of the Landé g-factor to % 5:1 eV À1 for this doping concentration and attribute the deviation from the commonly known factor of 6:3 eV À1 for slightly doped samples [20,21] to bandgap renormalization arising from the high doping concentration. The deviation of g à being a constant is less than 10 À3 T À1 which is at least a factor of 5 lower than for low doped GaAs at low temperatures.…”
mentioning
confidence: 99%
“…The k · p theory can describe quite well a wide range of low-temperature experimental results. When increasing temperature, however, discrepancies between the measured effective masses and Landé g-factor in GaAs and the corresponding predictions of the temperature-independent k·p theory have been observed (Hopkins et al, 1987;Hazama et al, 1986;Oestreich and Rühle, 1995;Hübner et al, 2006).…”
Section: H Spin-orbit Interaction: Temperature Effectsmentioning
confidence: 93%
“…For the case of GaAs C 1 = −0.02 (Hübner et al, 2006). In addition to the temperature dependence of the energy band-gaps one has to consider also the changes in the strength of the different momentum matrix elements.…”
Section: H Spin-orbit Interaction: Temperature Effectsmentioning
confidence: 99%