One- and two-dimensional spectral diffusion of type-II excitons in InP/InAs/InP core-multishell nanowires

Abstract: Spectral diffusion of type-II excitons in InP/InAs/InP core-multishell nanowires ͑CMNs͒ and type-I excitons in an InAs/InP single quantum well ͑SQW͒ was studied by means of time-resolved and spectrally resolved photoluminescence. InP/InAs/InP CMNs in hexagonal symmetry are made of six facets and six edges which work as two-dimensional quantum wells and one-dimensional quantum wires, respectively. At 5 K type-II excitons lose their energy in two stages. In the first stage, two-dimensional spectral diffusion tak… Show more

“…All peaks exhibit the same linear dependence on the excitation power without any clear blue shift indicating a type I band alignment. This is in contrast with earlier reports done by another group where optical investigations suggested a type II alignment [13,14]. Moreover, this study indicates the absence of the state filling effect's signature allowing the attribution of the higher energy side peaks to the excited state emission.…”

“…In particular, monolithic integration of emitters on silicon is still in great demand. While several studies have already been reported on the growth andz optical properties of InP/InAs/InP core-shell NWs on InP substrates [12][13][14], the study of the growth of such heterostructured NWs on Si substrates has not yet been reported. In this context, we have studied the growth of InP/InAs/InP NWs grown on Si substrates by VLS-assisted solid source MBE (ssMBE).…”

InAs/InP nanowires grown by catalyst assisted molecular beam epitaxy on silicon substrates

“…All peaks exhibit the same linear dependence on the excitation power without any clear blue shift indicating a type I band alignment. This is in contrast with earlier reports done by another group where optical investigations suggested a type II alignment [13,14]. Moreover, this study indicates the absence of the state filling effect's signature allowing the attribution of the higher energy side peaks to the excited state emission.…”

“…In particular, monolithic integration of emitters on silicon is still in great demand. While several studies have already been reported on the growth andz optical properties of InP/InAs/InP core-shell NWs on InP substrates [12][13][14], the study of the growth of such heterostructured NWs on Si substrates has not yet been reported. In this context, we have studied the growth of InP/InAs/InP NWs grown on Si substrates by VLS-assisted solid source MBE (ssMBE).…”

InAs/InP nanowires grown by catalyst assisted molecular beam epitaxy on silicon substrates

“…Polarized photoluminescence from single wurtzite InP/InAs/InP core-multishell nanowires Yasuaki Masumoto,1,a͒ The photoluminescence from single InP/InAs/InP core-multishell nanowires ͑CMNs͒ was highly linearly polarized in perpendicular to the nanowire long axis. Taking account of dielectric confinement of light field, we found the internal optical dipole squared perpendicular to the nanotube long axis d 0x 2 is larger than that parallel to the axis d 0z 2 by two orders of magnitude.…”

“…Nanotubes work as quantum wells and quantum wires and emit bright photoluminescence ͑PL͒ in the near infrared region. 1 Another unique feature of InP/InAs/InP CMNs is the wurtzite structure instead of zincblende structure for both InAs and InP bulk crystals. 2,3 The crystal field as well as spin-orbit interaction in the wurtzite structure split the top valence band into ⌫ 9 ͑A͒-state, ⌫ 7 ͑B͒-state, and ⌫ 7 ͑C͒-state.…”

Polarized photoluminescence from single wurtzite InP/InAs/InP core-multishell nanowires

“…Due to the small radial dimensions of the NWs the design of NW heterostructures is not limited by strain as in conventional planar molecular beam epitaxy (MBE) or metal-organic-vapor-phase-epitaxy (MOVPE) thus enabling the fabrication of a wide variety of radial heterostructures as e.g. GaAs/AlGaAs 7 , GaAs/GaP 12 and InP/InAs 13 core-shell NWs. Also axial NW heterostructures 7,14 become feasible that comprise segments of different semiconductor material with nanometer thickness along the NW [15][16][17] .…”

Population dynamics and dephasing of excitons and electron-hole pairs in polytype wurtzite/zinc-blende InP nanowires