Abstract
Integration of nanostructure lighting source arrays with well-defined emission wavelengths is of great importance for optoelectronic integrated monolithic circuitry. We report on the fabrication and optical properties of GaN-based p–n junction multishell nanotube microarrays with composition-modulated nonpolar m-plane InxGa1–xN/GaN multiple quantum wells (MQWs) integrated on c-sapphire or Si substrates. The emission wavelengths were controlled in the visible spectral range of green to violet by varying the indium mole fraction of the InxGa1–xN MQWs in the range 0.13 ≤ x ≤ 0.36. Homogeneous emission from the entire area of the nanotube LED arrays was achieved via the formation of MQWs with uniform QW widths and composition by heteroepitaxy on the well-ordered nanotube arrays. Importantly, the wavelength-invariant electroluminescence emission was observed above a turn-on of 3.0 V because both the quantum-confinement Stark effect and band filling were suppressed due to the lack of spontaneous inherent electric field in the m-plane nanotube nonpolar MQWs. The method of fabricating the multishell nanotube LED microarrays with controlled emission colors has potential applications in monolithic nonpolar photonic and optoelectronic devices on commonly used c-sapphire and Si substrates.
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Introduction
Semiconductor nanostructures and heterostructures have attracted considerable attention for applications in future high-performance optoelectronics1,2, including nanolasers3,4 and optoelectronic integrated circuits5,6,7. In particular, one-dimensional nanostructures prepared by a bottom-up approach, such as nanorods, nanowires and nanotubes, have important structural advantages compared with conventional planar films, including high-quality heteroepitaxial integration on (almost) arbitrary substrates (including III–V materials, Si and glass) with a small footprint8,9,10; a high aspect ratio with a large active area11 for high photon extraction (or absorption) efficiency as a waveguide12; and structural versatility to designed three-dimensional heterostructures with compositional modulation in the axial13,14,15,16, radial17,18,19, and/or both directions20,21,22,23,24. These advantages have contributed to significant improvements in the efficiency of optoelectronic devices2,12,14,25.
GaN-based nanomaterials26 are promising for full-color lighting and optoelectronic device applications20,25,27,28,29,30,31 owing to the solid-phase solubility of the InxGa1–xN alloy30,32,33. These nanostructures are typically grown along the polar c- or nonpolar m- or a- axes of wurtzite34,35,36. For this reason, the combination of such diverse growth directions with the axial14 or radial25 heterostructure geometries enables control over the polarity and optical properties of the heterostructures15,37. Recent developments of InGaN-based thin film light-emitting diodes (LEDs) have focused on semipolar or nonpolar heterostructures38,39 to resolve problems with the inherent internal electric field, which limits the efficiency of conventional c-plane planar LEDs40. Typically, r-and m-plane sapphire substrates are used to fabricate nonpolar a- and m-plane InGaN/GaN heterostructures, respectively41. The (100)γ-LiAlO2 substrate is often used to fabricate high-quality nonpolar InGaN-based LEDs, as this reduces the lattice mismatch to 1–2%42. Nevertheless, nonpolar InGaN heterostructures have an issue of the low indium incorporation for practical applications38. More importantly, the use of c-sapphire (or Si) is more cost-effective and enables large-area growth. Thus, there is demand for the fabrication of nonpolar InGaN-based heterostructures on c-sapphire substrates with wide tunability of the indium composition. Such requirements for LED applications can be achieved by growing c-axis elongated nanostructures with radial nonpolar heterostructures15,19,43,44,45.
For the reasons, there have been intensive studies on GaN-based multishell heterostructures grown on c-axis nanowires. The catalyst-free, controlled growth of core GaN nanowires36,46,47 successfully produced regularly arrayed radial nanowire heterostructures with m-plane InGaN multiple quantum wells (MQWs)21,48 for realizing the uniform electroluminescence (EL) emission colors19,43,44. Meanwhile, a nanotube can be another candidate for the core template to grow the multishell heterostructure. Distinguished from the solid nanowires, there are several potential advantages to use the ZnO nanotube as a core template for fabricating multishell heterostructure LEDs rather. For example, the shape-controlled epitaxy of nanowalls offers more degrees of freedom in diversely designing the size, shape and spacing of nanotube arrays49. This allows the fabrication of nano-LED arrays with the uniform EL emission. In addition, the metal-filled nanotube can further increase luminescent efficiency with surface plasmonic effect50 and/or efficient current injection through the metal core. Moreover, an ultrathin nanotube with a core cavity is expected to effectively release the strain caused by lattice misfit between GaN and ZnO through the large surface area51.
Here, we report on the fabrication and optical properties of GaN-based multishell nanotube heterostructure LED microarrays formed of composition-modulated m-plane {11–00} InxGa1–xN/GaN radial MQWs grown on core ZnO nanotube arrays. The optical properties, including modulation of the emission wavelength of the nanotube LEDs, were investigated by measuring the complementary cathodoluminescence (CL), photoluminescence (PL) and EL. We further discuss these luminescent properties and the correlation between the emission color and the spacing between nanotubes.
Results and Discussion
Structural and Compositional Characterizations of GaN Multishell Nanotube Heterostructures
Multishell nanotube heterostructure LED arrays were fabricated on n+-GaN/Al2O3(0001) substrates using a patterned SiO2 growth mask via selective metal–organic vapor phase epitaxy (MOVPE). Figure 1a shows a schematic diagram of the vertical multishell nanotube heterostructures LED arrays, consisting of core ZnO nanotubes, GaN radial p–n junctions and InxGa1–xN/GaN MQWs. The core ZnO nanotube arrays had a mean height in the range 4.0−4.5 μm and were prepared as a template for the growth of multishell nanotube heterostructures. The core diameter of the nanotubes was designed to be in the range 260−280 nm and the core–core spacing (i.e., pitch) was 2.5 μm; these features were defined using electron-beam lithographic patterning and subsequent etching of the SiO2 mask layer.
The multishell heterostructures were radially deposited on the outer surfaces of the ZnO nanotubes to form coaxial p–n junction LEDs. The GaN layer was coated on the ZnO nanotubes at a low growth temperature of 600 °C under nitrogen-ambient MOVPE growth conditions. Note that, without this low-temperature (LT) coating of the GaN layer (with a thickness of >50 nm), the core ZnO nanotubes were destroyed by the subsequent high-temperature process required for the MOVPE growth of the GaN-based LED structures (see Supplementary Fig. S1). The multishell layers of Si-doped n-GaN (with a thickness in the range 200–250 nm), three periods of InxGa1–xN/GaN MQWs and the outer shell of Mg-doped p-GaN (50–80-nm thick) were sequentially coated onto the LT-GaN/ZnO nanotubes using in-situ MOVPE. As a result of precisely-controlled selective-MOVPE growth process, the vertical nanotube LED arrays exhibited a well-defined spatial arrangement with uniform length and diameter, as shown by the field-emission scanning electron microscopy (FE-SEM) images in Fig. 1b. Details of the morphological changes and the microstructure of the radial multishell heterostructures are given in the Supplementary Information (see Figs S2–S4). Details of the fabrication and characterization can be found in the Methods section.
Controlling the indium mole fraction, x, in the InxGa1–xN MQWs by adjusting the growth temperature provides a simple and systematic route to tuning the emission color of the nanotube LED arrays. We fabricated multishell nanotube MQW heterostructures with 2.5-nm-thick InxGa1–xN layers and 20-nm-thick GaN layers at various growth temperatures in the range 670–760 °C using MOVPE. The InxGa1–xN/GaN MQWs exhibited {11–00} (i.e., m-plane) facets (see the transmission electron microscope (TEM) data shown in Fig. S3). Energy-dispersive x-ray (EDX) spectroscopy in scanning-TEM mode was used to determine the indium content in the InxGa1–xN MQWs. Figure 1c shows compositional line profiles of the indium and gallium L edges measured along the radial direction of the InxGa1–xN/GaN MQWs, revealing the formation of three pairs of MQWs. For the InxGa1–xN MQWs grown at 670, 720 and 760 °C, the mean indium mole fraction was 0.36 ± 0.06, 0.24 ± 0.05 and 0.13 ± 0.03, respectively. These data were measured for a series of single nanotube LEDs; greater deviation of the indium content was observed in the InxGa1–xN MQWs with a higher indium content, which was presumably due to the larger compositional fluctuations in the indium-rich growth conditions52,53.
Luminescent Characteristics of Single GaN Multishell Nanotube Heterostructures for LED
The optical properties of single nanotube LEDs were characterized using CL spectroscopy. The CL from a nanotube LED (measured at 80 K) exhibited two dominant emission peaks centered at ~2.6 and 3.48 eV, which were attributed to emission from the InGaN MQWs (IMQWs) and donor-bound excitons in the core n-GaN (In-GaN). The broad CL band in the range of 2.8–3.3 eV was attributed to band-to-Mg-doped acceptor emission and donor–acceptor pair recombination from the p-GaN outer shell layer (Ip-GaN)54,55.
Monochromatic mapping of the CL emission from a nanotube LED reveals spatial distribution of the IMQWs. Figure 2b shows an SEM image and corresponding monochromatic CL image scanned at a photon energy of 2.6 ± 0.04 eV for IMQWs along the stem of a nanotube LED. Both the CL image and the line profile of the IMQWs intensity revealed strong IMQWs along the entire length of the nanotube sidewalls, suggesting that the InxGa1–xN/GaN MQWs were formed conformally along the nanotube sidewalls.
Cross-sectional plan-view monochromatic CL mapping was used to visualize the spatial distribution of the distinct CL emissions. Figure 2c shows SEM images of single multishell nanotube heterostructures with a full LED structure, including the p–n junction and MQWs, together with a cross-sectional schematic diagram. From the monochromatic CL mapping at 2.6 ± 0.04 eV, IMQWs was clearly observed from the MQW region sandwiched between the n-GaN core and the p-GaN shell. This indicates that m-plane InGaN MQWs with a hexagonal cylindrical geometry were successfully formed in the nanotube LED. In contrast, In-GaN was only observed from the core, which corresponds to n-GaN/LT-GaN; the strong In-GaN outside the nanotube was attributed to the n-GaN substrate.
The ensemble-averaged luminescent characteristics of the nanotube LED arrays were investigated using PL spectroscopy. Figure 2d shows a series of PL spectra measured at 16 K obtained from the samples following consecutive growth of an n-GaN thin film, ZnO nanotubes, an n-GaN coating and a multishell coating of InxGa1–xN/GaN MQWs and p-GaN. The PL spectra were measured from 8 × 103 nanotube LEDs within the excitation laser spot. The strongest PL peak for the ZnO nanotubes was observed centered at 3.36 eV, which was attributed to neutral-donor-bound exciton emission (IZnO)56. Importantly, we observed IZnO after forming the n-GaN layer, which indicates that the LT-GaN coating protected the core ZnO nanotubes from the high-temperature n-GaN deposition process in the ambient hydrogen environment (Supplementary Fig. S5). The PL of the nanotube LED arrays exhibited three dominant emission peaks, corresponding to In-GaN (3.46 eV), Ip-GaN (2.9–3.3 eV) and IMQWs (2.4 eV) (see the red curve in Fig. 2d), similar to the CL spectra of a single nanotube LED. The full-width at half-maximum (FWHM) of IMQWs was ~0.27 eV, which is broader than that of a typical thin film of InxGa1–xN MQWs57 (ca. 0.12–0.15 eV). The broad spectrum was attributed to fluctuations in the indium content in the nanotube InxGa1–xN/GaN MQWs, as observed using EDX spectroscopy. The FWHM of the IMQWs CL was almost equal to that of the PL, which was presumably due to the homogeneous QW-luminescent characteristics over the entire area of the nanotube LED arrays.
The PL spectra of the nanotube MQWs were further investigated for the InxGa1–xN/GaN (2.5/20-nm thick) MQWs grown at various growth temperatures of 670–760 °C. From the series of 16-K PL spectra shown in Fig. 2e, the PL peak position for IMQWs gradually blueshifted from 525 nm (green) to 405 nm (violet) as the growth temperature increased from 670 to 760 °C. These results are consistent with the compositional analyses shown in Fig. 1.
Electroluminescence of GaN Multishell Nanotube LEDs
To inject current into the nanotube LED arrays, Ni/Au (10/10 nm) and Ti/Au (50/50 nm) Ohmic contacts were formed on the circumference of the outermost p-GaN shell and the n+-GaN substrate surface, respectively. A spin-on-glass (SOG) layer was used to provide electrical insulation between the two electrodes. Green, blue and violet emissions from nanotube LED arrays with a chip size of 100 × 100 μm2 were observed at forward biases in the range 5–8 V and were sufficiently strong to be observed with the naked eye under normal indoor illumination, as shown in Fig. 3a. Furthermore, EL from single-nanotube LEDs was clearly observed using an optical microscope, exhibiting green, blue and violet emissions, depending on the indium content of the MQWs. The high brightness of these nanotube LEDs was attributed to the large internal quantum efficiency (IQE) of InxGa1–xN (x~0.25 or ~0.31) nanotube MQWs, which was found to be 12 ± 4% by measuring the temperature-dependent PL spectra (Supplementary Fig. S6). This IQE is comparable to that of single-crystalline GaN nanowire-based LEDs29,58.
Figure 3b shows a series of room-temperature EL spectra of nanotube LED arrays with MQWs grown at temperatures of 670, 700, 730 and 760 °C. As with the PL spectra shown in Fig. 2e, the emission colors of the nanotube LED arrays were modulated from green to violet as the growth temperature increased. The EL peaks from the InxGa1–xN MQWs with average mole fractions of 0.36, 0.31, 0.25 and 0.13 were centered at 510, 485, 440 and 390 nm, respectively. The FHWM of EL peaks gradually increased from 0.36 to 0.49 eV as the In mole fraction increased from x = 0.13 to 0.36 in the InxGa1–xN MQWs (see Fig. 3b); this is consistent with the low-temperature PL spectra shown in Fig. 2e. In addition, the EL emission wavelength decreased monotonically as a function of the growth temperature from 510 nm (green) to 390 nm (violet), as shown in Fig. 3c. This was attributed to the temperature-dependent indium solubility of the m-plane radial MQWs formed in the nanotube geometry during MOVPE.
Dissimilar to other previous works, high indium content of m-plane sidewall InGaN QWs was achieved at relatively high growth temperature (Fig. 3c): e.g. Liao et al. reported m-plane InGaN QWs with indium mole fraction of 11–16% grown (with the nearest nanowire-to-nanowire spacing of 700 nm) at the growth temperature of 670–700 °C48 and Ra et al. demonstrated In0.08Ga0.92N coaxial QWs (with the spacing of ~200–300 nm) at 750 °C19. However, Koester et al. reported that the growth temperature of 750 °C yielded In0.2Ga0.8N MQWs (with the spacing of ~5–20 μm)18, implying that higher indium incorporation can be achieved with the greater nanowire spacing. It is well known that the lower density of nanostructure arrays enables more supply of precursors into the nanostructures during the growth, due to larger surface collection area59. This results in higher indium incorporation as observed in our nanotube LEDs with greater tube-to-tube spacing.
Figure 4a shows the current–voltage (I–V) characteristics of the nanotube LED arrays, which exhibited the typical rectifying behavior of a p–n junction, with a threshold voltage of ~3–4 V, dynamic resistance of ~3 × 102 Ω and small reverse-bias leakage current of 3.5 × 10−4 A at an applied bias of –5 V. The turn-on bias for EL was ~3.5 V, which is similar to the electrical threshold voltage. The emission intensity increased rapidly with the applied bias voltage. A LED chip with 100 × 100 μm2 area is composed of a parallel circuit of 1.85 × 103 nanotube LEDs and more than 95% LEDs among them emitted the EL (see Supplementary Fig. S7). Accordingly, the dynamic resistance of a single nanotube LED was calculated to be ~5.6 × 105 Ω, thus the electrical current flowing through each nanotube LED could be estimated to be a few μA at a typical operating forward electrical bias, which is consistent with previously reported values for single-nanowire LEDs18,25.
The EL emission exhibited very little blueshift of the peak position with increasing current, as shown in Fig. 4b. This was attributed to the absence of polarization-induced internal electric fields60 owing to the m-plane nonpolar nanotube MQWs, which is consistent with previous reports of single-nanowire LEDs15. We observed a small shift in the CL peak with increasing electron beam acceleration voltage in the range 5–15 kV (data not shown here), also indicating an absence of the quantum-confined Stark effect (QCSE) in the multishell MQWs. Such nonpolar features of the nanotube MQWs may be exploited to fabricate high-performance LEDs40 with suppressed QCSE61 or band-filling effects62. Applying a large bias did not result in additional EL peaks, such as emission from p-GaN due to electron overflow, which suggests that radiative recombination occurred exclusively in the nanotube MQWs.
Varying the geometrical arrangement represents another method to control the emission characteristics of nanotube MQWs since their growth rate is affected by the spacing between adjacent nanostructures. As the spacing increased from 2.5 to 6.0 μm, the EL wavelength shifted from 419 to 450 nm for a series of nanotube LED arrays that were prepared on a substrate during the same MOVPE growth batch (see Supplementary Fig. S8). This was attributed to an increase in the width Lw of the InGaN quantum wells of InxGa1–xN MQW heterostructures with the larger nanotube spacing. It is well-known that increasing the nanostructure spacing leads to an increase in the surface collection area during growth, allowing more growth precursor to migrate to the nanostructures63. This results in a higher growth rate in the growth regime whereby the precursor is shared between nanostructures. Similarly, with our MOVPE growth, a larger nanotube spacing resulted in a faster growth rate (data not shown here); thus Lw increased with the nanotube spacing, leading to a longer wavelength of the emitted light. This observation shows that position-controlled selective growth of multishell nanotube LEDs enables homogeneous luminescence with control over the emission color. Further optimization of the MOVPE conditions is required to provide homogenous emission with narrow spectral linewidths over the entire range of visible wavelengths.
Conclusion
We have demonstrated the fabrication of multishell nanotube LED arrays with composition-modulated nonpolar InxGa1–xN/GaN MQWs using selective MOVPE. The emission color was tuned over the visible spectral range from green to violet by varying the indium content of the InxGa1–xN MQWs, as confirmed by CL, PL and EDX spectroscopic analyses. Homogeneous emission from the entire area of the nanotube LED arrays was achieved via the formation of MQWs with uniform Lw and x via heteroepitaxy on the well-ordered nanotube arrays. Importantly, both the QCSE and band filling were suppressed in the nanotube LED arrays. This method of fabricating LED microarrays with controlled emission colors has potential applications in monolithic nonpolar photonic and optoelectronic devices on commonly used c-sapphire and Si substrates.
Methods
Position-controlled selective MOVPE
The multishell nanotube heterostructure LED arrays were fabricated using selective MOVPE method. The core ZnO nanotube arrays were grown on n+-GaN/Al2O3(0001) substrates coated with hole-patterned SiO2 growth-mask layer (thickness of 50 nm). The hole-openings were designed to be a regular triangular arrangement with a typical hole diameter of 250 nm and pitch of 2.5 μm by using electron-beam lithography and wet chemical etching. Diethylzinc (DEZn) and high-purity oxygen (>99.9999%) were used as reactants with flow rates of 3.0 and 20 standard centimeters per minute (sccm), respectively and high-purity argon as carrier gas. The reactor pressure and temperature were kept at 0.3 Torr and 600 °C for growing the ZnO nanotubes. The multishell heterostructures of LT-GaN layer (thickness of 60–80 nm), the multishell layers of Si-doped n-GaN (200–250 nm), InGaN/GaN (2.5/20 nm) MQWs and outermost shell of Mg-doped p-GaN (50–80 nm), were sequentially coated onto the ZnO nanotubes using III–nitride MOVPE with vertical rotating type reactor. Trimethylindium, trimethylgallium and ammonia were employed as reactants for III–nitrides with hydrogen (or nitrogen) carrier gas. The growths of n- and p-GaN were performed at the substrate temperatures of 1080 and 1000 °C with doping precursors of ditertiarybutylsilane (flow rate of <0.3 sccm) and magnesocene (350 sccm), respectively. The typical resistivity and carrier concentration of the n-GaN were measured to be 6 × 10–3 Ω·cm and 4 × 1018 electrons cm–3, respectively; those of the p-GaN were 5–10 Ω·cm and 0.8–1.3 × 1017 holes cm–3 after p-type activation at 700 °C. In order to change the indium composition of InxGa1–xN layers, MQWs-growth temperature was varied in the range of 650–800 °C.
Device fabrication
The nanotube LEDs were fabricated by making Ohmic contacts of Ni/Au (10/10 nm) and Ti/Au (50/50 nm) bilayers on both the circumferential surface of outermost p-GaN shell and the n+-GaN, respectively. The two different metal electrodes were isolated with insulator by coating a spin-on-glass (SOG) layer between them. To expose the circumferential sidewall surface of nanotube heterostructures, wet chemical etching of SOG was performed using buffered-oxide etchant. The exposed sidewall height by etching was typically 1.5–2.0 μm (Supplementary Fig. S9a–c). To avoid the local current injection only through tips of individual nanotube LEDs, the Ni/Au electrode was conformally deposited on the sidewall surface of nanotube LEDs using an oblique angle metal evaporation technique (upper panel of Supplementary Fig. 9d). It is noted that the conformal deposition of continuous electrode layers on the circumference of nanotube heterostructures allows uniform current injection for operating entire nanotube LED arrays (see Supplementary Fig. S9d). Otherwise, the electrical current is not efficiently supplied into the nanotube LED arrays, which deteriorate the yield of EL emission. After the Ni/Au bilayer deposition, thermal annealing and sputtering deposition of indium tin oxide (150 nm) layer were performed for highly conducting semitransparent p-electrode.
Characterizations
The morphology and structural characteristics were investigated using field-emission SEM (Philips, XL30SFEG) and high-resolution TEM (FEI, Tecnai G2 F20). For TEM analysis, samples were milled with cross sections orthogonal and parallel to the length direction by 30 kV-accelerated Ga ions using a focused ion beam machine (FIB; FEI, NOVA200 Nanolab) in the dual beam mode. The acceleration voltage of gallium ions was decreased from 30 to 5 kV at the finishing stage to reduce the damage of the sample and an inevitable contamination with gallium ions. The compositional line-profile of the InxGa1–xN/GaN MQWs along its radial direction was obtained from EDX spectroscopy in the scanning-TEM mode of the TEM facility: the x was determined by measuring the relative ratio of x-ray counts of gallium and indium L edges.
The PL spectra were obtained at 16 K and room temperature using the 325 nm line of a continuous-wave He–Cd laser for excitation. A CL facility (Gatan, MonoCL3 + ) attached to the SEM (Hitachi, S-4300) was employed. The CL images and spectra were measured at 80 K and room temperature using a 10-kV electron beam. The spectral resolution of the employed high-resolution CL measurement system was as accurate as ± 8 meV. The measurements of EL spectra and I–V characteristics were performed simultaneously. The electrical and luminescent properties of the devices were performed by measuring I–V characteristic curves and EL spectra using sourcemeter (Keithley, 2600) and monochromator with charge-coupled device detector (Dongwoo Optron, MonoRa 150i), respectively. For the electrical measurement duty-cycle operation with a cycle period 20 ms and a pulse of 2 ms was used at room temperature.
Additional Information
How to cite this article: Hong, Y. et al. Emission color-tuned light-emitting diode microarrays of nonpolar InxGa1-xN/GaN multishell nanotube heterostructures. Sci. Rep. 5, 18020; doi: 10.1038/srep18020 (2015).
References
Schubert, E. F. & Kim, J. K. Solid-state light sources getting smart. Science 308, 1274–1278 (2005).
Wallentin, J. et al. InP Nanowire Array Solar Cells Achieving 13.8% Efficiency by Exceeding the Ray Optics Limit. Science 339, 1057–1060 (2013).
Li, K. H., Liu, X., Wang, Q., Zhao, S. & Mi, Z. Ultralow-threshold electrically injected AlGaN nanowire ultraviolet lasers on Si operating at low temperature. Nat. Nanotechnol. 10, 140–144 (2015).
Chen, R. et al. Nanolasers grown on silicon. Nat. Photon. 5, 170–175 (2011).
Huang, Y., Duan, X. & Lieber, C. M. Nanowires for integrated multicolor nanophotonics. Small 1, 142–147 (2005).
Kim, J.-H., Ko, Y.-H., Gong, S.-H., Ko, S.-M. & Cho, Y.-H. Ultrafast single photon emitting quantum photonic structures based on a nano-obelisk. Sci. Rep. 3, 2150 (2013).
Holmes, M. J., Choi, K., Kako, S., Arita, M. & Arakawa, Y. Room-Temperature Triggered Single Photon Emission from a III-Nitride Site-Controlled Nanowire Quantum Dot. Nano Lett. 14, 982–986 (2014).
Park, W. I., Yi, G.-C., Kim, M. & Pennycook, S. J. ZnO Nanoneedles Grown Vertically on Si Substrates by Non-Catalytic Vapor-Phase Epitaxy. Adv. Mater. 14, 1841–1843 (2002).
Tomioka, K., Motohisa, J., Hara, S., Hiruma, K. & Fukui, T. GaAs/AlGaAs Core Multishell Nanowire-Based Light-Emitting Diodes on Si. Nano Lett. 10, 1639–1644 (2010).
Choi, J. H. et al. Nearly single-crystalline GaN light-emitting diodes on amorphous glass substrates. Nat. Photon. 5, 763–769 (2011).
Tian, B. et al. Coaxial silicon nanowires as solar cells and nanoelectronic power sources. Nature 449, 885–889 (2007).
An, S. J., Chae, J. H., Yi, G.-C. & Park, G. H. Enhanced light output of GaN-based light-emitting diodes with ZnO nanorod arrays. Appl. Phys. Lett. 92, 121108 (2008).
Park, W. I., Yi, G. C., Kim, M. & Pennycook, S. J. Quantum confinement observed in ZnO/ZnMgO nanorod heterostructures. Adv. Mater. 15, 526–529 (2003).
Kim, H. M. et al. High-brightness light emitting diodes using dislocation-free indium gallium nitride/gallium nitride multiquantum-well nanorod arrays. Nano Lett. 4, 1059–1062 (2004).
Ra, Y.-H., Navamathavan, R., Yoo, H.-I. & Lee, C.-R. Single Nanowire Light-Emitting Diodes Using Uniaxial and Coaxial InGaN/GaN Multiple Quantum Wells Synthesized by Metalorganic Chemical Vapor Deposition. Nano Lett. 14, 1537–1545 (2014).
Nguyen, H. P. T. et al. Engineering the Carrier Dynamics of InGaN Nanowire White Light-Emitting Diodes by Distributed p-AlGaN Electron Blocking Layers. Sci. Rep. 5, 7744 (2015).
Jang, E. S. et al. Quantum confinement effect in ZnO/Mg0.2Zn0.8O multishell nanorod heterostructures. Appl. Phys. Lett. 88, 023102 (2006).
Koester, R. et al. M-Plane Core–Shell InGaN/GaN Multiple-Quantum-Wells on GaN Wires for Electroluminescent Devices. Nano Lett. 11, 4839–4845 (2011).
Ra, Y.-H., Navamathavan, R., Park, J.-H. & Lee, C.-R. Coaxial InxGa1-xN/GaN Multiple Quantum Well Nanowire Arrays on Si(111) Substrate for High-Performance Light-Emitting Diodes. Nano Lett. 13, 3506–3516 (2013).
Hong, Y. J. et al. Visible-Color-Tunable Light-Emitting Diodes. Adv. Mater. 23, 3284–3288 (2011).
Yeh, T.-W. et al. InGaN/GaN Multiple Quantum Wells Grown on Nonpolar Facets of Vertical GaN Nanorod Arrays. Nano Lett. 12, 3257–3262 (2012).
Liao, C.-H. et al. Geometry and composition comparisons between c-plane disc-like and m-plane core-shell InGaN/GaN quantum wells in a nitride nanorod. Opt. Express 20, 15859–15871 (2012).
Riley, J. R. et al. Three-Dimensional Mapping of Quantum Wells in a GaN/InGaN Core–Shell Nanowire Light-Emitting Diode Array. Nano Lett. 13, 4317–4325 (2013).
Jung, B. O. et al. Highly ordered catalyst-free InGaN/GaN core–shell architecture arrays with expanded active area region. Nano Energy 11, 294–303 (2015).
Qian, F., Gradečak, S., Li, Y., Wen, C.-Y. & Lieber, C. M. Core/multishell nanowire heterostructures as multicolor, high-efficiency light-emitting diodes. Nano Lett. 5, 2287–2291 (2005).
Li, S. F. & Waag, A. GaN based nanorods for solid state lighting. J. Appl. Phys. 111, 071101 (2012).
Sekiguchi, H., Kishino, K. & Kikuchi, A. Emission color control from blue to red with nanocolumn diameter of InGaN/GaN nanocolumn arrays grown on same substrate. Appl. Phys. Lett. 96, 231104 (2010).
Lin, H.-W., Lu, Y.-J., Chen, H.-Y., Lee, H.-M. & Gwo, S. InGaN/GaN nanorod array white light-emitting diode. Appl. Phys. Lett. 97, 073101 (2010).
Guo, W., Zhang, M., Banerjee, A. & Bhattacharya, P. Catalyst-Free InGaN/GaN Nanowire Light Emitting Diodes Grown on (001) Silicon by Molecular Beam Epitaxy. Nano Lett. 10, 3355–3359 (2010).
Nguyen, H. P. T., Cui, K., Zhang, S., Fathololoumi, S. & Mi, Z. Full-color InGaN/GaN dot-in-a-wire light emitting diodes on silicon. Nanotechnology 22, 445202 (2011).
Bavencove, A. L. et al. Submicrometre resolved optical characterization of green nanowire-based light emitting diodes. Nanotechnology 22, 345705 (2011).
Kuykendall, T., Ulrich, P., Aloni, S. & Yang, P. Complete composition tunability of InGaN nanowires using a combinatorial approach. Nat. Mater. 6, 951–956 (2007).
Ko, Y.-H. et al. Red Emission of InGaN/GaN Double Heterostructures on GaN Nanopyramid Structures. ACS Photonics 2, 515–520 (2015).
Kuykendall, T. et al. Crystallographic alignment of high-density gallium nitride nanowire arrays. Nat. Mater. 3, 524–528 (2004).
Hong, Y. J., Lee, C.-H., Park, J. B., An, S. J. & Yi, G.-C. GaN nanowire/thin film vertical structure p-n junction light-emitting diodes. Appl. Phys. Lett. 103, 261116 (2013).
Lin, Y.-T., Yeh, T.-W., Nakajima, Y. & Dapkus, P. D. Catalyst-Free GaN Nanorods Synthesized by Selective Area Growth. Adv. Funct. Mater. 24, 3162–3171 (2014).
Ko, Y.-H., Song, J., Leung, B., Han, J. & Cho, Y.-H. Multi-color broadband visible light source via GaN hexagonal annular structure. Sci. Rep. 4, 5514 (2014).
Masui, H., Nakamura, S., DenBaars, S. P. & Mishra, U. K. Nonpolar and Semipolar III-Nitride Light-Emitting Diodes: Achievements and Challenges. IEEE Trans. Electron Devices 57, 88–100 (2010).
Jang, J., Woo, S., Min, D. & Nam, O. Recent Advances in Nonpolar and Semipolar InGaN Light-Emitting Diodes (LEDs). J. Nanosci. Nanotechnol. 15, 1895–1906 (2015).
Cho, J., Schubert, E. F. & Kim, J. K. Efficiency droop in light-emitting diodes: Challenges and Countermeasures. Laser Photon. Rev. 7, 408–421 (2013).
Craven, M. D., Lim, S. H., Wu, F., Speck, J. S. & DenBaars, S. P. Structural characterization of nonpolar (11(2)over-bar0) a-plane GaN thin films grown on (1(1)over-bar02) r-plane sapphire. Appl. Phys. Lett. 81, 469–471 (2002).
Waltereit, P. et al. Growth of M-plane GaN(1(1)over-bar-00) on gamma-LiAlO2(100). J. Cryst. Growth 218, 143–147 (2000).
Bavencove, A. L. et al. Light emitting diodes based on GaN core/shell wires grown by MOVPE on n-type Si substrate. Electron. Lett. 47, 765–766 (2011).
Chen, H.-S. et al. Light-emitting device with regularly patterned growth of an InGaN/GaN quantum-well nanorod light-emitting diode array. Opt. Lett. 38, 3370–3373 (2013).
Lee, C.-H. et al. GaN/In1-xGaxN/GaN/ZnO nanoarchitecture light emitting diode microarrays. Appl. Phys. Lett. 94, 121108 (2009).
Hersee, S. D., Sun, X. Y. & Wang, X. The controlled growth of GaN nanowires. Nano Lett. 6, 1808–1811 (2006).
Wang, X. et al. Continuous-Flow MOVPE of Ga-Polar GaN Column Arrays and Core-Shell LED Structures. Cryst. Growth Des. 13, 3475–3480 (2013).
Liao, C.-H. et al. Dependencies of the emission behavior and quantum well structure of a regularly-patterned, InGaN/GaN quantum-well nanorod array on growth condition. Opt. Express 22, 17303–17319 (2014).
Hong, Y. J. et al. Shape-Controlled Nanoarchitectures Using Nanowalls. Adv. Mater. 21, 222–226 (2009).
Yoo, J., Ma, X., Tang, W. & Yi, G.-C. Metal-Lined Semiconductor Nanotubes for Surface Plasmon-Mediated Luminescence Enhancement. Nano Lett. 13, 2134–2140 (2013).
Hong, Y. J. et al. Structural and optical characteristics of GaN/ZnO coaxial nanotube heterostructure arrays for light-emitting device applications. New J. Phys. 11, 125021 (2009).
Lin, Y.-S. et al. Dependence of composition fluctuation on indium content in InGaN/GaN multiple quantum wells. Appl. Phys. Lett. 77, 2988–2990 (2000).
Duxbury, N. et al. Indium segregation in InGaN quantum-well structures. Appl. Phys. Lett. 76, 1600–1602 (2000).
Reshchikov, M. A., Yi, G. C. & Wessels, B. W. Behavior of 2.8- and 3.2-eV photoluminescence bands in Mg-doped GaN at different temperatures and excitation densities. Phys. Rev. B 59, 13176–13183 (1999).
Viswanath, A. K. et al. Magnesium acceptor levels in GaN studied by photoluminescence. J. Appl. Phys. 83, 2272–2275 (1998).
Meyer, B. K. et al. Bound exciton and donor–acceptor pair recombinations in ZnO. Phys. Status Solidi B 241, 231–260 (2004).
Masui, H. et al. Quantum-confined Stark effect on photoluminescence and electroluminescence characteristics of InGaN-based light-emitting diodes. J. Phys. D: Appl. Phys. 41, 165105 (2008).
Armitage, R. & Tsubaki, K. Multicolour luminescence from InGaN quantum wells grown over GaN nanowire arrays by molecular-beam epitaxy. Nanotechnology 21, 195202 (2010).
Jensen, L. E. et al. Role of surface diffusion in chemical beam epitaxy of InAs nanowires. Nano Lett. 4, 1961–1964 (2004).
Schmidt, M. C. et al. High Power and High External Efficiency m -Plane InGaN Light Emitting Diodes. Jpn. J. Appl. Phys. 46, L126–128 (2007).
Chichibu, S., Azuhata, T., Sota, T. & Nakamura, S. Spontaneous emission of localized excitons in InGaN single and multiquantum well structures. Appl. Phys. Lett. 69, 4188–4190 (1996).
Wang, T., Nakagawa, D., Lachab, M., Sugahara, T. & Sakai, S. Optical investigation of InGaN/GaN multiple quantum wells. Appl. Phys. Lett. 74, 3128–3130 (1999).
Borgstrom, M. T., Immink, G., Ketelaars, B., Algra, R. & Bakkers, E. P. A. M. Synergetic nanowire growth. Nat. Nanotechnol. 2, 541–544 (2007).
Acknowledgements
This research was supported by Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education, Science and Technology (MEST) (Grant No. NRF-2013R1A1A2058744) and by the Human Resources Development of the Korea Institute of Energy Technology Evaluation and Planning (KETEP) grant funded by the Korea government Ministry of Trade, Industry & Energy (No. 20154030200630). The work of Seoul National University was supported by Future-based Technology Development Program (Nano Fields) through the NRF funded by the MEST (NRF-2014M3A7B4051589). The experiments were partly performed at CINT, a U.S. Department of Energy, Office of Basic Energy Sciences User Facility at Los Alamos National Laboratory (Contract DE-AC52-06NA25396) and Sandia National Laboratories (Contract DE-AC04-94AL85000).
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Y.J.H., C.-H.L. and G.-C.Y. conceived and designed the experiments. Y.J.H. and C.-H.L. conducted MOVPE growth of nano-LED structures and device fabrications and characterizations. J.Y., Y.-J.K., J.J. and M.K. contributed to optical characterizations, ZnO growth and TEM–EDX analyses. Y.J.H. and G.-C.Y. wrote the manuscript, which was read, edited and approved by all the authors.
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Hong, Y., Lee, CH., Yoo, J. et al. Emission color-tuned light-emitting diode microarrays of nonpolar InxGa1–xN/GaN multishell nanotube heterostructures. Sci Rep 5, 18020 (2015). https://doi.org/10.1038/srep18020
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DOI: https://doi.org/10.1038/srep18020
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