Your search keyword '"Junzhuan Wang"' showing total 11 results

1. Advanced radial junction thin film photovoltaics and detectors built on standing silicon nanowires.

Author

Ting Zhang, Junzhuan Wang, Linwei Yu, Jun Xu, and Pere Roca i Cabarrocas

Subjects

*SILICON nanowires, *THIN films, *SILICON solar cells, *PHOTOVOLTAIC power generation, *STRUCTURAL optimization, *PLANAR antennas, *BIOMIMETIC materials, *BLIND source separation

Abstract

Three-dimensional (3D) construction of radial junction hydrogenated amorphous silicon (a-Si:H) thin film solar cells on standing silicon nanowires (SiNWs) is a promising strategy to maximize the light harvesting performance and improve the photocarrier collection in an optimized junction configuration. The unique light in-coupling and absorption behaviour in the antenna-like 3D photonic structures also necessitates a set of new theoretical models and simulation tools to design, predict and optimize the photovoltaic performance of radial junction solar cells, which can be rather different from planar junction solar cells. Recently, the performance of radial junction a-Si:H thin film solar cells has progressed steadily to a level comparable or even superior to that of their planar counterparts, with plenty of room for further improvement. This review will first address the growth strategy and critical parameter control of SiNWs produced via a plasma-assisted low-temperature vapour–liquid–solid procedure using low-melting-point metals as the catalyst. Then, the construction of high-performance radial junction thin film solar cells over the standing SiNW matrix, as well as their optimal structural designs, will be introduced. At the end, the new applications of 3D radial junction units will be summarized, which include, for example, the construction of very flexible, low-cost and efficient a-Si:H solar cells with the highest power-to-weight ratio, the demonstration of highly sensitive solar-blind photodetectors operating at the ultraviolet wavelength spectrum and the development of novel biomimetic radial tandem junction photodetectors with an intrinsic red–green–blue (RGB) colour distinguishing capability. [ABSTRACT FROM AUTHOR]

Published

2019

2. Understanding Light Harvesting in Radial Junction Amorphous Silicon Thin Film Solar Cells.

Author

Linwei Yu, Misra, Soumyadeep, Junzhuan Wang, Shengyi Qian, Foldyna, Martin, Jun Xu, Yi Shi, Johnson, Erik, and Cabarrocas, Pere Roca i

Subjects

*ENERGY harvesting, *AMORPHOUS silicon, *SOLAR cells, *ELLIPSOMETRY, *SILICON nanowires, *SCANNING electron microscopy, *PLASMA-enhanced chemical vapor deposition

Abstract

The radial junction (RJ) architecture has proven beneficial for the design of a new generation of high performance thin film photovoltaics. We herein carry out a comprehensive modeling of the light in-coupling, propagation and absorption profile within RJ thin film cells based on an accurate set of material properties extracted from spectroscopic ellipsometry measurements. This has enabled us to understand and evaluate the impact of varying several key parameters on the light harvesting in radially formed thin film solar cells. We found that the resonance mode absorption and antenna-like light in-coupling behavior in the RJ cell cavity can lead to a unique absorption distribution in the absorber that is very different from the situation expected in a planar thin film cell, and that has to be taken into account in the design of high performance RJ thin film solar cells. When compared to the experimental EQE response of real RJ solar cells, this modeling also provides an insightful and powerful tool to resolve the wavelength-dependent contributions arising from individual RJ units and/or from strong light trapping due to the presence of the RJ cell array. [ABSTRACT FROM AUTHOR]

Published

2014

3. Understanding Light Harvesting in Radial Junction Amorphous Silicon Thin Film Solar Cells.

Author

Linwei Yu, Soumyadeep Misra, Junzhuan Wang, Shengyi Qian, Martin Foldyna, Jun Xu, Yi Shi, Erik Johnson, and Pere Roca i Cabarrocas

Subjects

*AMORPHOUS silicon, *THIN films, *SOLAR cells, *PHOTOVOLTAIC power generation, *ELLIPSOMETRY

Abstract

The radial junction (RJ) architecture has proven beneficial for the design of a new generation of high performance thin film photovoltaics. We herein carry out a comprehensive modeling of the light in-coupling, propagation and absorption profile within RJ thin film cells based on an accurate set of material properties extracted from spectroscopic ellipsometry measurements. This has enabled us to understand and evaluate the impact of varying several key parameters on the light harvesting in radially formed thin film solar cells. We found that the resonance mode absorption and antenna-like light in-coupling behavior in the RJ cell cavity can lead to a unique absorption distribution in the absorber that is very different from the situation expected in a planar thin film cell, and that has to be taken into account in the design of high performance RJ thin film solar cells. When compared to the experimental EQE response of real RJ solar cells, this modeling also provides an insightful and powerful tool to resolve the wavelength-dependent contributions arising from individual RJ units and/or from strong light trapping due to the presence of the RJ cell array. [ABSTRACT FROM AUTHOR]

Published

2014

4. Deterministic Line-Shape Programming of Silicon Nanowires for Extremely Stretchable Springs and Electronics.

Author

Zhaoguo Xue, Mei Sun, Taige Dong, Zhiqiang Tang, Yaolong Zhao, Junzhuan Wang, Xianlong Wei, Linwei Yu, Qing Chen, Jun Xu, Yi Shi, Kunji Chen, and Roca i Cabarrocas, Pere

Subjects

*CRYSTALLINITY, *CRYSTAL structure, *SILICON nanowires, *NANOSTRUCTURED materials, *SCANNING electron microscopy

Abstract

Line-shape engineering is a key strategy to endow extra stretchability to 1D silicon nanowires (SiNWs) grown with self-assembly processes. We here demonstrate a deterministic line-shape programming of in-plane SiNWs into extremely stretchable springs or arbitrary 2D patterns with the aid of indium droplets that absorb amorphous Si precursor thin film to produce ultralong c-Si NWs along programmed step edges. A reliable and faithful single run growth of c-SiNWs over turning tracks with different local curvatures has been established, while high resolution transmission electron microscopy analysis reveals a high quality monolike crystallinity in the line-shaped engineered SiNW springs. Excitingly, in situ scanning electron microscopy stretching and current-voltage characterizations also demonstrate a superelastic and robust electric transport carried by the SiNW springs even under large stretching of more than 200%. We suggest that this highly reliable line-shape programming approach holds a strong promise to extend the mature c-Si technology into the development of a new generation of high performance biofriendly and stretchable electronics. [ABSTRACT FROM AUTHOR]

Published

2017

5. Heteroepitaxial Writing of Silicon-on-Sapphire Nanowires.

Author

Mingkun Xu, Zhaoguo Xue, Jimmy Wang, Yaolong Zhao, Yao Duan, Guangyao Zhu, Linwei Yu, Jun Xu, Junzhuan Wang, Yi Shi, Kunji Chen, and Pere Roca i Cabarrocas

Subjects

*THIN films, *NANOWIRES, *NANOELECTRONICS, *SAPPHIRES, *FABRICATION (Manufacturing), *OPTOELECTRONICS

Abstract

The heteroepitaxial growth of crystal silicon thin films on sapphire, usually referred to as SoS, has been a key technology for high-speed mixed-signal integrated circuits and processors. Here, we report a novel nanoscale SoS heteroepitaxial growth that resembles the in-plane writing of self-aligned silicon nanowires (SiNWs) on R-plane sapphire. During a low-temperature growth at <350 °C, compared to that required for conventional SoS fabrication at >900 °C, the bottom heterointerface cultivates crystalline Si pyramid seeds within the catalyst droplet, while the vertical SiNW/catalyst interface subsequently threads the seeds into continuous nanowires, producing self-oriented in-plane SiNWs that follow a set of crystallographic directions of the sapphire substrate. Despite the low-temperature fabrication process, the field effect transistors built on the SoS-SiNWs demonstrate a high on/off ratio of >5 × 104 and a peak hole mobility of >50 cm2/V·s. These results indicate the novel potential of deploying in-plane SoS nanowire channels in places that require high-performance nanoelectronics and optoelectronics with a drastically reduced thermal budget and a simplified manufacturing procedure. [ABSTRACT FROM AUTHOR]

Published

2016

6. Structural evolution of Ge-rich Si1-xGex films deposited by jet-ICPCVD.

Author

Yu Wang, Meng Yang, Gang Wang, Xiaoxu Wei, Junzhuan Wang, Yun Li, Youdou Zheng, Yi Shi, and Zewen Zou

Subjects

*GERMANIUM silicide films, *PLASMA-enhanced chemical vapor deposition, *INDUCTIVELY coupled plasma spectrometry

Abstract

Amorphous Ge-rich Si1-xGex films with local Ge-clustering were deposited by dualsource jet-type inductively coupled plasma chemical-vapor deposition (jet-ICPCVD). The structural evolution of the deposited films annealed at various temperatures (Ta) is investigated. Experimental results indicate that the crystallization occurs to form Ge and Si clusters as Ta = 500 °C. With raising Ta up to 900 °C, Ge clusters percolate together and Si diffuses and redistributes to form a Ge/SiGe core/shell structure, and some Ge atoms partially diffuse to the surface as a result of segregation. The present work will be helpful in understanding the structural evolution process of a hybrid SiGe films and beneficial for further optimizing the microstructure and properties. [ABSTRACT FROM AUTHOR]

Published

2015

7. Bi-Sn alloy catalyst for simultaneous morphology and doping control of silicon nanowires in radial junction solar cells.

Author

Zhongwei Yu, Jiawen Lu, Shengyi Qian, Misra, Soumyadeep, Linwei Yu, Jun Xu, Ling Xu, Junzhuan Wang, Yi Shi, Kunji Chen, and Cabarrocas, Pere Roca i

Subjects

*N-type semiconductors, *BISMUTH alloys, *SILICON nanowires synthesis, *DOPING agents (Chemistry), *SOLAR cells, *VAPOR-liquid equilibrium

Abstract

Low-melting point metals such as bismuth (Bi) and tin (Sn) are ideal choices for mediating a low temperature growth of silicon nanowires (SiNWs) for radial junction thin film solar cells. The incorporation of Bi catalyst atoms leads to sufficient n-type doping in the SiNWs core that exempts the use of hazardous dopant gases, while an easy morphology control with pure Bi catalyst has never been demonstrated so far. We here propose a Bi-Sn alloy catalyst strategy to achieve both a beneficial catalyst-doping and an ideal SiNW morphology control. In addition to a potential of further growth temperature reduction, we show that the alloy catalyst can remain quite stable during a vapor-liquid-solid growth, while providing still sufficient n-type catalyst-doping to the SiNWs. Radial junction solar cells constructed over the alloy-catalyzed SiNWs have demonstrated a strongly enhanced photocurrent generation, thanks to optimized nanowire morphology, and largely improved performance compared to the reference samples based on the pure Bi or Sn-catalyzed SiNWs. [ABSTRACT FROM AUTHOR]

Published

2015

8. Mo-O bond doping and related-defect assisted enhancement of photoluminescence in monolayer MoS2.

Author

Xiaoxu Wei, Zhihao Yu, Ying Cheng, Linwei Yu, Junzhuan Wang, Xinran Wang, Yi Shi, Fengrui Hu, Xiaoyong Wang, and Min Xiao

Subjects

*PHOTOLUMINESCENCE, *MOLYBDENUM disulfide, *MOLYBDATES, *QUANTUM efficiency, *TRIONS (Nuclear physics), *MONOMOLECULAR films

Abstract

In this work, we report a strong photoluminescence (PL) enhancement of monolayer MoS2 under different treatments. We find that by simple ambient annealing treatment in the range of 200 °C to 400 °C, the PL emission can be greatly enhanced by a factor up to two orders of magnitude. This enhancement can be attributed to two factors: first, the formation of Mo-O bonds during ambient exposure introduces an effective p-doping in the MoS2 layer; second, localized electrons formed around Mo-O bonds related defective sites where the electrons can be effectively localized with higher binding energy resulting in efficient radiative excitons recombination. Time resolved PL decay measurement showed that longer lifetime of the treated sample consistent with the higher quantum efficiency in PL. These results give more insights to understand the luminescence properties of the MoS2. [ABSTRACT FROM AUTHOR]

Published

2014

9. Fabrication of lateral electrodes on semiconductor nanowires through structurally matched insulation for functional optoelectronics.

Author

Yun Sheng, Huabin Sun, Jianyu Wang, Fan Gao, Junzhuan Wang, Lijia Pan, Lin Pu, Youdou Zheng, and Yi Shi

Subjects

*OPTOELECTRONICS, *NANOWIRES, *SEMICONDUCTOR nanoparticles, *ELECTRODES, *THERMAL insulation, *ZINC oxide

Abstract

A strategy of using structurally matched alumina insulation to produce lateral electrodes on semiconductor nanowires is presented. Nanowires in the architecture are structurally matched with alumina insulation using selective anodic oxidation. Lateral electrodes are fabricated by directly evaporating metallic atoms onto the opposite sides of the nanowires. The integrated architecture with lateral electrodes propels carriers to transport them across nanowires and is crucially beneficial to the injection/extraction in optoelectronics. The matched architecture and the insulating properties of the alumina layer are investigated experimentally. ZnO nanowires are functionalized into an ultraviolet photodiode as an example. The present strategy successfully implements an advantageous architecture and is significant in developing diverse semiconductor nanowires in optoelectronic applications. [ABSTRACT FROM AUTHOR]

Published

2013

10. Germanium quantum dot infrared photodetectors addressed by self-aligned silicon nanowire electrodes.

Author

Yaolong Zhao, Lingfei Li, Shuaishuai Liu, Junzhuan Wang, Jun Xu, Yi Shi, Kunji Chen, Pere Roca i Cabarrocas, and Linwei Yu

Subjects

*QUANTUM dots, *PHOTODETECTORS, *GERMANIUM, *SILICON nanowires, *ELECTRODES, *INFRARED absorption

Abstract

Germanium quantum dots (GeQDs), addressed by self-aligned and epitaxial silicon nanowires (SiNWs) as electrodes, represent the most fundamental and the smallest units that can be integrated into Si optoelectronics for 1550 nm wavelength detection. In this work, individual GeQD photodetectors have been fabricated based on a low temperature self-condensation of uniform amorphous Si (a-Si)/a-Ge bilayers at 300 °C, led by rolling indium (In) droplets. Remarkably, the diameter of the GeQD nodes can be independently controlled to achieve wider GeQDs for maximizing infrared absorption with narrower SiNW electrodes to ensure a high quality Ge/Si hetero-epitaxial connection. Importantly, these hetero GeQD/SiNW photodetectors can be deployed into predesigned locations for scalable device fabrication. The photodetectors demonstrate a responsivity of 1.5 mA W−1 and a photoconductive gain exceeding 102 to the communication wavelength signals, which are related to the beneficial type-II Ge/Si alignment, gradient Ge/Si epitaxial transition and a larger QD/NW diameter ratio. These results indicate a new approach to batch-fabricate and integrate GeQDs for ultra-compact Si-compatible photodetection and imaging applications. [ABSTRACT FROM AUTHOR]

Published

2020

11. Electrically tunable optical properties of few-layer black arsenic phosphorus.

Author

Li Yu, Zhen Zhu, Anyuan Gao, Junzhuan Wang, Feng Miao, Yi Shi, and Xiaomu Wang

Subjects

*ARSENIC, *PHOSPHORUS, *MOLYBDENUM

Abstract

Black arsenic phosphorus (b-AsP) is a promising two-dimensional material for various optoelectronic applications, bridging the wavelength gap between two-dimensional molybdenum disulfide and graphene. In particular, it has intriguing potential in photodetectors and great advantages in the mid-infrared field. However, its optoelectronic modulation has yet to be elucidated, which requires a fundamental understanding of its field-effect optical modulation. Here, we report the measurements of the lower-energy infrared anisotropic optical response of thin b-AsP under different electrical gating. We reveal that in addition to band edge absorption, amplitude modulation of sub-band absorption up to ten percent is also obtained in reflection extinction. These in-gap absorptions are attributed to spin–orbital coupling and free carrier absorption. Our results suggest the important potential for use of b-AsP in mid-infrared optoelectronic modulator applications. [ABSTRACT FROM AUTHOR]

Published

2018