Observation of single-optical-phonon emission

Heiblum, M.; Galbi, D; Weckwerth, M.V.

doi:10.1103/physrevlett.62.1057

Cited by 50 publications

(14 citation statements)

References 15 publications

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“…The peak energies, which were lower by about 3-4 meV than the corresponding Fermi level in the emitter (noted by the crossing of the dotted lines with the energy axis), and the narrow distribution width (-S meV) were both expected for the normal energy distributions injected by 50-nm-wide, 20-meV-high tunnel barriers. 6 These results proved that tunneling was the injection mechanism in our induced barriers. At their lower-energy tails the distributions rise again, most probably due to lower-energy electrons that are excited from the Fermi sea in the base by scattered (nonballistic) electrons.…”

Section: Lateral Tunneling Ballistic Transport and Spectroscopy In supporting

confidence: 51%

Lateral tunneling, ballistic transport, and spectroscopy in a two-dimensional electron gas

et al. 1989

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We report a direct observation, via electron energy spectroscopy, of lateral tunneling and lateral ballistic electron transport in a two-dimensional electron gas (2D EG). This was accomplished through the use of a novel transistor structure employing two potential barriers, induced by 50-nm-wide metal gates deposited on a GaAs/AlGaAs selectively doped heterostructure. Hot electrons with very narrow energy distributions ( -5 meV wide) have been observed to ballistically traverse 2D EG regions ==170 nm wide with a mean free path of about 480 nm. PACS numbers: 73.40.Gk, 73.20.Dx Ballistic transport of hot electrons was established recently in n "'"-type GaAs by the use of energy spectroscopy in a hot-electron structure. l These experiments utilized an injector at one end of a transport region and a spectrometer at the other end, with the electrons moving normal to the plane of the layers (vertical transport). This technique proved to be very powerful since it permitted the energy distribution and the mean free path of the ballistic electrons to be determined. The very recent demonstration of quantized resistance in a confined quasi-two-dimensional electron gas (2D EG) 2,3 strongly suggests ballistic transport of electrons near equilibrium parallel to the interface between the layers (lateral transport). We report here the first utilization of an energy spectroscopy technique to establish directly lateral tunneling through an induced potential barrier and the existence of lateral ballistic transport in a 2D EG. This was done by inducing two closely spaced potential barriers in the 2D EG via two narrow Schottky metal gates deposited on the surface of the structure. One barrier was employed as a tunnel injector and the second as a spectrometer. We have measured narrow hot-electron distributions ballistically traversing lateral 2D EG regions 170 nm wide, and have estimated their mean free path.Several structures were made on a selectively doped GaAs/AlGaAs heterostructure grown by molecularbeam epitaxy. On top of an undoped GaAs buffer layer, an undoped AlGaAs layer (50 nm thick, AlAs mole fraction x=34%) was grown, followed by a thin heavily doped GaAs cap layer (15 nm thick). A sheet of Si atoms, with an areal density of -2x 10 12 cm ~2, was deposited under overpressure of As when growth of the AlGaAs was interrupted (planar doping), 30 nm away from the GaAs buffer layer; these supply the electrons in the 2D EG [ Fig. 1(a)]. The 2D EG had a carrier density of 3x10 ll cm -2 and a mobility of 3xl0 5 cm 2 /Vsec at 4.2 K. Two parallel AuPd gates, each 52 nm wide and 0.5 jam long, were patterned 93 nm apart using electron-beam nanolithography, on a 5-^m-wide isolated 2D EG line [ Fig. 1(b)]. Ohmic contacts were made to the three regions defined by both gates. Biasing the gates negatively with respect to the central region between them (called the base) depleted the 2D EG underneath the gates and prevented the free motion of the equilibrium electrons among the three regions [emitter (E), base (B), and collector (C)]. The...

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Section: Lateral Tunneling Ballistic Transport and Spectroscopy In supporting

confidence: 51%

Lateral tunneling, ballistic transport, and spectroscopy in a two-dimensional electron gas

et al. 1989

Self Cite

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“…This agrees with previous studies on the dominant hole-optical phonon interactions. 38 Our result is an experimental validation for the theoretical evaluation of phonon-assisted IVB absorption, for which a theoretical model is typically employed to predict the role of phonons, with justification from other experiments. 13 The major role of 3 × TO(Ŵ) instead of one TO phonon, although confirmed experimentally, remains to be explained, which may require further study based on this observation.…”

Section: /∇mentioning

confidence: 64%

Direct observation of spin-orbit splitting and phonon-assisted optical transitions in the valence band by internal photoemission spectroscopy

Lao

Perera

et al. 2013

Phys. Rev. B

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We employ internal photoemission spectroscopy to directly measure the valence-band Van Hove singularity, and identify phonons participating in indirect intervalence-band optical transitions. Photoemission of holes photoexcited through transitions between valence bands displays a clear and resolvable threshold, unlike previous reports of interband critical points which become obscure in doped materials. We also demonstrate the enhancement of optical phonon-assisted features primarily contributing to the photoemission yield. This result is evidence of the relaxation of photoexcited hot holes through intravalence-band scatterings in heterojunctions, which contrast with intervalence-band scatterings in bulks.

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“…where τ LO is the electron-phonon scattering time (~ 1ps) [13], and 1/τ S1 is the kinetic-energy dependent spin relaxation rate. We assume that the contribution of the Elliot-Yafet (EY) [14] mechanism to spin relaxation in these measurements can be neglected, because our experiments are not performed on narrow-gap compounds.…”

Section: Spin-relaxation Modelmentioning

confidence: 99%

Voltage dependent spin tunneling and spin relaxation in spin-leds

Isakovic

Hitt

2011

2011 IEEE GCC Conference and Exhibition (GCC)

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Spin diodes are potential building blocks of spin transistors, themselves units for future spintronics "microchips" for quantum information processing. Ferromagnet-semiconductor Schottky diodes are useful model devices that allow for understanding of basic physical and electronic processes in transport of spinpolarized electrons across the interface between a conventional ferromagnet (itself a natural reservoir of spins) and a spin hospitable semiconductor like galliumarsenide (GaAs), where spin-carrying electrons can be used for quantum information processing. This paper will introduce a model that explains experimentally observed voltage dependence of finite spin transfer efficiency, using Schottky tunneling contact, and drift-diffusion equations. In the same framework we present a rateequation based explanation for voltage dependent spin relaxation of hot electrons, which has also been experimentally observed in spin light emitting diodes (spin-LEDs). Based on this model, we present device suggestions that are realizable within the modern semiconductor growth and nanoprocessing R&D sector.

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Observation of single-optical-phonon emission

Cited by 50 publications

References 15 publications

Lateral tunneling, ballistic transport, and spectroscopy in a two-dimensional electron gas

Lateral tunneling, ballistic transport, and spectroscopy in a two-dimensional electron gas

Direct observation of spin-orbit splitting and phonon-assisted optical transitions in the valence band by internal photoemission spectroscopy

Voltage dependent spin tunneling and spin relaxation in spin-leds

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