Optical orientation of donor-bound excitons in nanosized InP/InGaP islands

“…27 Although the Hanle measurement is static, it has high sensitivity in measuring the spin-dephasing time of carriers in QDs. 23,24,28 We succeeded in measuring the Hanle effect of charge-tunable InP QDs with high sensitivity and accuracy of the circular polarization ͑0.1%͒. We observed optical orientation of the spin of the doped electrons under quasiresonant excitation and measured a spin-dephasing time T 2 * of 1.7 ns at 5 K, exceeding the recombination lifetime of 250 ps.…”

“…A long spin-dephasing time T 2 * , which is the lifetime of coherent superposition of spin-up and spin-down states, is absolutely imperative for the implementation of spin-based quantum computing and storage. Although a few studies have been made on spin-dephasing relaxation in charged QDs, [23][24][25][26] studies about the mechanisms of spin dephasing are still at the elementary stage.…”

Spin dephasing of doped electrons in charge-tunable InP quantum dots: Hanle-effect measurements

“…27 Although the Hanle measurement is static, it has high sensitivity in measuring the spin-dephasing time of carriers in QDs. 23,24,28 We succeeded in measuring the Hanle effect of charge-tunable InP QDs with high sensitivity and accuracy of the circular polarization ͑0.1%͒. We observed optical orientation of the spin of the doped electrons under quasiresonant excitation and measured a spin-dephasing time T 2 * of 1.7 ns at 5 K, exceeding the recombination lifetime of 250 ps.…”

“…A long spin-dephasing time T 2 * , which is the lifetime of coherent superposition of spin-up and spin-down states, is absolutely imperative for the implementation of spin-based quantum computing and storage. Although a few studies have been made on spin-dephasing relaxation in charged QDs, [23][24][25][26] studies about the mechanisms of spin dephasing are still at the elementary stage.…”

Spin dephasing of doped electrons in charge-tunable InP quantum dots: Hanle-effect measurements

“…Excitation of QD nanostructures by circularly polarized light provides the optical pumping of resident QD electrons [10,11,12]. A plausible scenario is the capture of single carriers into the dots.…”

Stabilization of the Electron-Nuclear Spin Orientation in Quantum Dots by the Nuclear Quadrupole Interaction

“…Recently, negative PL polarization of the trion with nonresonant circularly polarized excitation was explained with two alternative models [12,29,30]. The first [29,30] is based on the creation and accumulation of dark excitons due to single spin flips of delocalized holes.…”

“…The first [29,30] is based on the creation and accumulation of dark excitons due to single spin flips of delocalized holes. Subsequent capture by a negatively charged QD and recombination leads to negative polarization.…”

Polarized Fine Structure in the Photoluminescence Excitation Spectrum of a Negatively Charged Quantum Dot