Molecular beam epitaxial growth and characterization of non-tapered InN nanowires on Si(111)

Kibria

et al. 2012

Phys. Rev. B

In the present work, photoluminescence characteristics of intrinsic and Si-doped InN nanowires were studied in details. For intrinsic InN nanowires, the emission is due to band-to-band carrier recombination with the peak energy at ∼ 0.64 eV (at 300 K), and may involve free-exciton emission at low temperatures. The PL spectra exhibit a strong dependence on optical excitation power and temperature, which can be well characterized by the presence of very low residual electron density, and the absence or negligible level of surface electron accumulation. In comparison, the emission of Si-doped InN nanowires is characterized by the presence of two distinct peaks located at ∼ 0.65 eV and ∼ 0.73 − 0.75 eV (at 300 K). Detailed studies further suggest that these low-energy and highenergy peaks can be ascribed to band-to-band carrier recombination in the relatively low-doped nanowire bulk region and Mahan exciton emission in the high-doped nanowire near-surface region, respectively; this is a natural consequence of dopants surface segregation. The resulting surface electron accumulation and Fermi-level pinning, due to the enhanced surface doping, is confirmed by angle-resolved X-ray photoelectron spectroscopy measurements on Si-doped InN nanowires, which is in direct contrast to the absence, or negligible level of surface electron accumulation in intrinsic InN nanowires. This work has elucidated the role of charge carrier concentration and distribution on the optical properties of InN nanowires.

Section: Experimental Setupsmentioning

confidence: 66%

Section: Experimental Setupsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Understanding the role of Si doping on surface charge and optical properties: Photoluminescence study of intrinsic and Si-doped InN nanowires

Kibria

et al. 2012

Phys. Rev. B

“…In fact, a number of recent studies indicate that the MBE-grown III-nitride nanowires could be substrate independent [95][96][97][98][99], i.e., the MBE-grown III-nitride nanowires can be essentially formed on any substrate. For example, GaN, InGaN/GaN dot-in-a-wire, and InN nanowire structures have been demonstrated on silicon oxide [95,[99][100][101].…”

Section: Conclusion and Future Prospectsmentioning

confidence: 99%

Recent Advances on p-Type III-Nitride Nanowires by Molecular Beam Epitaxy

2017

Crystals

Self Cite

p-Type doping represents a key step towards III-nitride (InN, GaN, AlN) optoelectronic devices. In the past, tremendous efforts have been devoted to obtaining high quality p-type III-nitrides, and extraordinary progress has been made in both materials and device aspects. In this article, we intend to discuss a small portion of these processes, focusing on the molecular beam epitaxy (MBE)-grown p-type InN and AlN-two bottleneck material systems that limit the development of III-nitride near-infrared and deep ultraviolet (UV) optoelectronic devices. We will show that by using MBE-grown nanowire structures, the long-lasting p-type doping challenges of InN and AlN can be largely addressed. New aspects of MBE growth of III-nitride nanostructures are also discussed.

Axial GaN Nanowire‐Based LEDs

Wang

Nguyen

Wide Band Gap Semiconductor Nanowires 2

et al. 2014

Axial GaN Nanowire-based LEDs IntroductionCurrent solid state lamps rely on the use of blue light-emitting diodes (LEDs) and the generation of green/red light by phosphor-based down-conversion process. The phosphor-based approach, however, has several fundamental drawbacks, which include a poor color rendition particularly in the red spectral range, significant efficiency loss related to the Stokes shift and phosphor degradation [SCH 05]. In this regard, there is an urgent need to develop high-efficiency GaN-based LEDs in the green and red wavelength range, which has been limited by the lack of suitable substrates, as well as the large lattice mismatch between InN and GaN and the resulting large densities of dislocations and polarization fields for conventional quantum well (QW) LEDs. Moreover, the external quantum efficiency (EQE) of GaN-based QW LEDs generally decreases considerably with increasing injection current. Probable causes for the efficiency droop include defect-assisted carrier leakage [VAM 09], Auger recombination [SHE 07], carrier delocalization [MON 07], inefficient carrier injection related to the presence of internal polarization fields [KIM 07] and the poor hole transport/injection process [XIE 08]. Such critical issues can be addressed, by and large, by utilizing one-dimensional (1D) III-nitride nanowire (NW)/nanorod heterostructures, which can be grown directly on low-cost, large area foreign substrates, and can offer significantly reduced dislocation densities and strain distribution, due to the effective lateral stress relaxation [GLA 06] (for more details, we can refer to Chapter 2 in Vol. 1 [CON 14]). Moreover, such nanoscale structures promise improved light extraction efficiency, due to the large surface-to-volume ratios [HEN 11].III-nitride NW LEDs can be fabricated by using either the top-down or bottomup method. In the last decade, tremendous progress has been made in the epitaxial Chapter written