Zinc oxide thin-film random lasers on silicon substrate

Yu, Siu Fung; Yuen, Clement; Lau, Shu Ping; Lee, H. W.

doi:10.1063/1.1719279

Cited by 140 publications

(100 citation statements)

References 8 publications

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“…[1][2][3] ZnO is nontoxic, biocompatible, and low cost, making it a potential candidate for industrial applications. 4 ZnO films have been deposited by different techniques such as chemical vapor deposition, 5 vacuum evaporation, 6 radiofrequency (RF) sputtering, 7 solgel, 8 molecular-beam epitaxy, 9 pulsed laser deposition, 10 atomic layer deposition, 11 chemical vapor deposition, 12 vacuum arc technique, 13 and spray pyrolysis. 14 Among these techniques, the spray pyrolysis method possesses the advantages of high deposition rate with good control of the physical properties of the deposited layers and production of large-area device-quality material.…”

Section: Introductionmentioning

confidence: 99%

Structural, Optical, and Electrical Properties of Nb-Doped ZnO Thin Films Prepared by Spray Pyrolysis Method

Gokulakrishnan

Parthiban

Jeganathan

et al. 2011

Journal of Elec Materi

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Niobium (Nb) doping (0 at.% to 3 at.%) in ZnO thin films prepared by the chemical spray pyrolysis method at a substrate temperature of 400°C enhances the optical and electrical properties but deteriorates the structural quality of the films. The films are polycrystalline with hexagonal structure having a preferential orientation along the (002) crystallographic direction. The film doped with 3 at.% Nb demonstrates a maximum average transmittance of $83% in the visible region. A strong blue emission is recorded for both pure and doped films, and the intensity is substantially enhanced with Nb doping due to interface and valence-band transitions. Vacuum annealing at 400°C for 60 min improves the electrical characteristics of the films, and the highest mobility of 71 cm 2 /V s is achieved for the 1 at.% Nb-doped ZnO films.

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Section: Introductionmentioning

confidence: 99%

Structural, Optical, and Electrical Properties of Nb-Doped ZnO Thin Films Prepared by Spray Pyrolysis Method

Gokulakrishnan

Parthiban

Jeganathan

et al. 2011

Journal of Elec Materi

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“…Two ZnO epilayers, sample A (ZnO(100 nm)/ SiO 2 (400 nm)/Si (substrate)) and sample B (ZnO(100 nm)/ MgO(200 nm)/ZnO(100 nm)/SiO 2 (400 nm)/Si (substrate)), were fabricated by the filtered cathodic vacuum arc technique and thermal annealing. [4,5] It is shown that the top (002)-oriented ZnO active layer of sample A (sample B) experiences tensile (compressive) strain along the c-axis.[5] Figure 1 shows the lasing spectra versus temperature, T, for the two samples under optical excitation at ∼ 2 × I th , where I th is the pump threshold intensity at the corresponding T. It can be shown that sample A (sample B) demonstrates RT EHP (FE) radiative recombination with discrete peaks at ∼ 393 nm (∼ 380 nm), and the corresponding lasing mechanism is attributed to random laser action. [5] With the increase of temperature, the shrinkage of the bandgap red-shifts the lasing peaks.…”

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confidence: 97%

“…Investigations of the temperature dependence of stimulated EES emission of the ZnO films on sapphire and the ZnO/ (Mg, Zn)O superlattices on ScAlMgO 4 have found that the corresponding T c values are 67 and 87 K, respectively. [7] These samples (i.e., without grain boundaries) show smaller values of T c (i.e., poorer high-T performance) than those of our ZnO epilayers.…”

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confidence: 98%

“…Figure 4b shows the RT gate-to-gate I-V curves of sample A before and after annealing. The I-V curve of sample A before annealing (i.e., with very small and closely packed grains [4] ) exhibits a linear I-V relationship. However, the I-V curve of sample A after annealing exhibits fast (slow) oscillation with a period of ∼ 2 mV (∼ 40-50 mV), which indicates there is charging and discharging of injected carriers [12] inside the ZnO grains (ZnO nanocrystals inside the grains).…”

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confidence: 98%

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High‐Temperature Lasing Characteristics of ZnO Epilayers

Lau

et al. 2006

Advanced Materials

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ZnO thin films deposited on sapphire, silicon, and fused silica substrates have demonstrated UV excitonic lasing at room temperature (RT) under optical excitation. [1][2][3][4][5] Because of the large binding energy (∼ 60 meV) of ZnO, it is also expected that the ZnO films can sustain excitonic lasing at high temperature. Recent studies of ZnO epilayers have observed spontaneous emission from free-excition (FE) radiative recombination as well as stimulated emission from exciton-exciton scattering (EES) and electron-hole-plasma (EHP) radiative recombination at temperatures up to ∼ 550 K.[2] ZnO nanosheets can also sustain photoluminescence (PL) at ∼ 870 K.[6]These studies have suggested the potential of using ZnO to fabricate high-temperature UV excitonic lasers. However, investigations on the temperature dependence of stimulated excitonic emission from ZnO films and ZnO/ZnMgO superlattices have shown that the corresponding characteristic temperature, which reflects the quality of the high-temperature performance of the lasers, is less than 90 K in a narrow range of temperature between 294 and 377 K. [7] In order to obtain high-quality excitonic lasing at high temperature, it is necessary to improve the characteristic temperature of the ZnO lasers. In this communication, strained ZnO epilayers with nanostructures are proposed to sustain coherent random lasing at high temperature. It is found that the ZnO epilayers can achieve lasing up to 570 K, and the corresponding characteristic temperature can be as high as 127 K. This is because i) the formation of ZnO nanostructures prevents the spreading of excited carriers over the pumped region and ii) the closed-loop path of light by random laser action allows the size variation of random cavities. Therefore, lasing can be obtained from the ZnO epilayers at high temperature. Two ZnO epilayers, sample A (ZnO(100 nm)/ SiO 2 (400 nm)/Si (substrate)) and sample B (ZnO(100 nm)/ MgO(200 nm)/ZnO(100 nm)/SiO 2 (400 nm)/Si (substrate)), were fabricated by the filtered cathodic vacuum arc technique and thermal annealing. [4,5] It is shown that the top (002)-oriented ZnO active layer of sample A (sample B) experiences tensile (compressive) strain along the c-axis.[5] Figure 1 shows the lasing spectra versus temperature, T, for the two samples under optical excitation at ∼ 2 × I th , where I th is the pump threshold intensity at the corresponding T. It can be shown that sample A (sample B) demonstrates RT EHP (FE) radiative recombination with discrete peaks at ∼ 393 nm (∼ 380 nm), and the corresponding lasing mechanism is attributed to random laser action. [5] With the increase of temperature, the shrinkage of the bandgap red-shifts the lasing peaks. Furthermore, it is observed that the full width at half maximum of the lasing peaks for both samples remains less than 0.4 nm for T up to 570 K. Hence, it is shown that coherent random lasing, which arises from the formation of closed-loop paths of light, [8] can be sustained inside the annealed ZnO epilayers with nanostructures at high...

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“…This is because the use of random media will avoid the difficulty of cleaving smooth facets from the ZnO material in order to sustain lasing, leading to low-cost, high-volume fabrication of UV laser diodes. [2] Recently, we have demonstrated effective UV random lasing from patterned ZnO-SiO 2 nanocomposite films under optical excitation. UV random lasing can be achieved in these films because the appropriate patterning of ZnO clusters enhances the optical quality (i.e., higher gain and lower loss) of the random media.…”

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confidence: 99%

UV Random Lasing Action in p‐SiC(4H)/i‐ZnO–SiO₂ Nanocomposite/n‐ZnO:Al Heterojunction Diodes

Leong

2006

Advanced Materials

111

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UV random lasing in p–i–n ZnO‐based heterojunction diodes is achieved. The UV emission originates from the use of an intrinsic ZnO–SiO2 nanocomposite layer; the use of ZnO powders can improve the electrical‐to‐optical conversion efficiency of the heterojunction. The patterned ZnO clusters in the SiO2 matrix enhance the quality of the random media (see figure) thus sustaining the random lasing action. If low‐index, p‐doped, wide‐bandgap materials are used as the hole‐injection layer, strong coherent random lasing could be achieved.

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Zinc oxide thin-film random lasers on silicon substrate

Cited by 140 publications

References 8 publications

Structural, Optical, and Electrical Properties of Nb-Doped ZnO Thin Films Prepared by Spray Pyrolysis Method

Structural, Optical, and Electrical Properties of Nb-Doped ZnO Thin Films Prepared by Spray Pyrolysis Method

High‐Temperature Lasing Characteristics of ZnO Epilayers

UV Random Lasing Action in p‐SiC(4H)/i‐ZnO–SiO₂ Nanocomposite/n‐ZnO:Al Heterojunction Diodes

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Zinc oxide thin-film random lasers on silicon substrate

Cited by 140 publications

References 8 publications

Structural, Optical, and Electrical Properties of Nb-Doped ZnO Thin Films Prepared by Spray Pyrolysis Method

Structural, Optical, and Electrical Properties of Nb-Doped ZnO Thin Films Prepared by Spray Pyrolysis Method

High‐Temperature Lasing Characteristics of ZnO Epilayers

UV Random Lasing Action in p‐SiC(4H)/i‐ZnO–SiO2 Nanocomposite/n‐ZnO:Al Heterojunction Diodes

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UV Random Lasing Action in p‐SiC(4H)/i‐ZnO–SiO₂ Nanocomposite/n‐ZnO:Al Heterojunction Diodes