Your search keyword '"Peizhuan Chen"' showing total 10 results

1. Investigation on high-efficiency Ga0.51In0.49P/In0.01Ga0.99As/Ge triple-junction solar cells for space applications

Author

Lei Zhang, Pingjuan Niu, Yuqiang Li, Minghui Song, Jianxin Zhang, Pingfan Ning, and Peizhuan Chen

Subjects

Physics, QC1-999

Abstract

Ga0.51In0.49P/In0.01Ga0.99As/Ge triple-junction solar cells for space applications were grown on 4 inch Ge substrates by metal organic chemical vapor deposition methods. The triple-junction solar cells were obtained by optimizing the subcell structure, showing a high open-circuit voltage of 2.77 V and a high conversion efficiency of 31% with 30.15 cm2 area under the AM0 spectrum at 25 °C. In addition, the In0.01Ga0.99As middle subcell structure was focused by optimizing in order to improve the anti radiation ability of triple-junction solar cells, and the remaining factor of conversion efficiency for middle subcell structure was enhanced from 84% to 92%. Finally, the remaining factor of external quantum efficiency for triple-junction solar cells was increased from 80% to 85.5%.

Published

2017

2. Quasi-crystal photonic structures for fullband absorption enhancement in thin film silicon solar cells

Author

Peizhuan Chen, Xiansong Fu, Liyuan Yu, Guanghua Yang, Guofu Hou, Niu Pingjuan, Jianjun Zhang, and Qi Hua Fan

Subjects

010302 applied physics, Silicon, Renewable Energy, Sustainability and the Environment, business.industry, Photovoltaic system, chemistry.chemical_element, 02 engineering and technology, Hybrid solar cell, Quantum dot solar cell, 021001 nanoscience & nanotechnology, 01 natural sciences, Polymer solar cell, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Monocrystalline silicon, Optics, chemistry, 0103 physical sciences, Optoelectronics, sense organs, Plasmonic solar cell, Thin film, 0210 nano-technology, business

Abstract

To further increase the efficiency of thin film solar cells, it is critical to enhance the absorption over the full spectral wavelength range in which solar cells generate electricity. In this letter, we present a fullband absorption enhancement method for n-i-p thin film silicon solar cells based on a Quasi-Crystal Structure (QCS) by superimposing Ag random nanotextures on periodically patterned Micro-Cone Substrates. Both light in-coupling and light trapping abilities are significantly improved thanks to the reduction of front-surface reflection originated from the gradually changed refractive index of preserved micro-cone profile after film deposition and the richer guided mode resonances caused by the QCS. An initial efficiency of 10.4% is obtained for QCS-based hydrogenated amorphous silicon germanium (a-SiGe:H) solar cells, which outperforms the planar (efficiency of 7.5%) and randomly nanotextured (efficiency of 8.7%) counter part by 38.7% and 19.5%, respectively. The QCS can also be duplicated for other thin film photovoltaic devices and provides a new approach for creating high-efficiency thin-film solar cells.

Published

2018

3. Combining randomly textured surfaces and one-dimensional photonic crystals as efficient light-trapping structures in hydrogenated amorphous silicon solar cells

Author

Xiaodan Zhang, Qian Huang, Peizhuan Chen, Qi Hua Fan, Ying Zhao, Guofu Hou, Jianjun Zhang, and Jian Ni

Subjects

Amorphous silicon, Photocurrent, Materials science, Silicon, Renewable Energy, Sustainability and the Environment, business.industry, chemistry.chemical_element, Light scattering, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, law.invention, chemistry.chemical_compound, Optics, chemistry, law, Solar cell, Optoelectronics, Texture (crystalline), business, Optical path length, Photonic crystal

Abstract

One of the foremost challenges in achieving high-efficiency thin-film silicon solar cells is in devising an efficient light trapping system because of the short optical path length imposed by the inherent thin absorption layers. In this paper, an efficient light trapping system is proposed using a combination of randomly textured surfaces and a one-dimensional photonic crystal (randomly textured photonic crystal; RTPC). The influence of the texture on the optical performance of RTPCs is discussed using the results of an experiment and a finite-difference time-domain simulation. This RTPC back reflector (BR) can provide high reflectivity and strong light scattering, resulting in an increased photocurrent density of the hydrogenated amorphous silicon (a-Si:H) solar cell. As a result, the highly textured RTPC BR yielded an efficiency of 9.6% for a-Si:H solar cell, which is much higher than the efficiency of 7.6% on flat AZO/Ag BR and 9.0% on textured AZO/Ag BR. This RTPC BR provides a new approach for creating high-efficiency, low-cost thin-film silicon solar cells.

Published

2015

4. Optimal design of one-dimensional photonic crystal back reflectors for thin-film silicon solar cells.

Author

Peizhuan Chen, Guofu Hou, Jianjun Zhang, Xiaodan Zhang, and Ying Zhao

Subjects

*OPTIMAL designs (Statistics), *ONE-dimensional flow, *PHOTONIC crystals, *FINITE difference time domain method, *PHOTONIC band gap structures, *SHORT-circuit currents

Abstract

For thin-film silicon solar cells (TFSC), a one-dimensional photonic crystal (1D PC) is a good back reflector (BR) because it increases the total internal reflection at the back surface. We used the plane-wave expansion method and the finite difference time domain (FDTD) algorithm to simulate and analyze the photonic bandgap (PBG), the reflection and the absorption properties of a 1D PC and to further explore the optimal 1D PC design for use in hydrogenated amorphous silicon (a-Si:H) solar cells. With identified refractive index contrast and period thickness, we found that the PBG and the reflection of a 1D PC are strongly influenced by the contrast in bilayer thickness. Additionally, light coupled to the top three periods of the 1D PC and was absorbed if one of the bilayers was absorptive. By decreasing the thickness contrast of the absorptive layer relative to the non-absorptive layer, an average reflectivity of 96.7% was achieved for a 1D PC alternatively stacked with a-Si:H and SiO2 in five periods. This reflectivity was superior to a distributed Bragg reflector (DBR) structure with 93.5% and an Ag film with 93.4%. n-i-p a-Si:H solar cells with an optimal 1D PC-based BR offer a higher short-circuit current density than those with a DBR-based BR or an AZO/Ag-based BR. These results provide new design rules for photonic structures in TFSC. [ABSTRACT FROM AUTHOR]

Published

2014

5. Photonic Structures for Light Trapping in Thin Film Silicon Solar Cells: Design and Experiment

Author

Guofu Hou, Peizhuan Chen, Yi Ding, and Qi Hua Fan

Subjects

Materials science, 02 engineering and technology, 01 natural sciences, Light scattering, law.invention, law, 0103 physical sciences, Solar cell, Materials Chemistry, back reflector, Thin film, Optical path length, Photonic crystal, 010302 applied physics, business.industry, Scattering, Surfaces and Interfaces, 021001 nanoscience & nanotechnology, Surfaces, Coatings and Films, thin-film silicon solar cell, Solar cell efficiency, lcsh:TA1-2040, Optoelectronics, light-trapping, Photonics, lcsh:Engineering (General). Civil engineering (General), 0210 nano-technology, business, photonic crystal

Abstract

One of the foremost challenges in designing thin-film silicon solar cells (TFSC) is devising efficient light-trapping schemes due to the short optical path length imposed by the thin absorber thickness. The strategy relies on a combination of a high-performance back reflector and an optimized texture surface, which are commonly used to reflect and scatter light effectively within the absorption layer, respectively. In this paper, highly promising light-trapping structures based on a photonic crystal (PC) for TFSCs were investigated via simulation and experiment. Firstly, a highly-reflective one-dimensional photonic crystal (1D-PC) was designed and fabricated. Then, two types of 1D-PC-based back reflectors (BRs) were proposed: Flat 1D-PC with random-textured aluminum-doped zinc oxide (AZO) or random-textured 1D-PC with AZO. These two newly-designed BRs demonstrated not only high reflectivity and sufficient conductivity, but also a strong light scattering property, which made them efficient candidates as the electrical contact and back reflector since the intrinsic losses due to the surface plasmon modes of the rough metal BRs can be avoided. Secondly, conical two-dimensional photonic crystal (2D-PC)-based BRs were investigated and optimized for amorphous a-SiGe:H solar cells. The maximal absorption value can be obtained with an aspect ratio of 1/2 and a period of 0.75 µm. To improve the full-spectral optical properties of solar cells, a periodically-modulated PC back reflector was proposed and experimentally demonstrated in the a-SiGe:H solar cell. This periodically-modulated PC back reflector, also called the quasi-crystal structure (QCS), consists of a large periodic conical PC and a randomly-textured Ag layer with a feature size of 500–1000 nm. The large periodic conical PC enables conformal growth of the layer, while the small feature size of Ag can further enhance the light scattering. In summary, a comprehensive study of the design, simulation and fabrication of 1D-PC- and 2D-PC-based back reflectors for TFSCs was carried out. Total absorption and device performance enhancement were achieved with the novel PC light-trapping systems because of their high reflectivity or high scattering property. Further research is necessary to illuminate the optimal structure design of PC-based back reflectors and high solar cell efficiency.

Published

2017

6. Investigation on high-efficiency Ga0.51In0.49P/In0.01Ga0.99As/Ge triple-junction solar cells for space applications.

Author

Lei Zhang, Pingjuan Niu, Yuqiang Li, Minghui Song, Jianxin Zhang, Pingfan Ning, and Peizhuan Chen

Subjects

SILICON solar cells, METAL organic chemical vapor deposition, SOLAR cells, SOLAR cell efficiency, OPEN-circuit voltage

Abstract

Ga0.51In0.49P/In0.01Ga0.99As/Ge triple-junction solar cells for space applications were grown on 4 inch Ge substrates by metal organic chemical vapor deposition methods. The triple-junction solar cells were obtained by optimizing the subcell structure, showing a high open-circuit voltage of 2.77 V and a high conversion efficiency of 31% with 30.15 cm2 area under the AM0 spectrum at 25°C. In addition, the In0.01Ga0.99As middle subcell structure was focused by optimizing in order to improve the anti radiation ability of triple-junction solar cells, and the remaining factor of conversion efficiency for middle subcell structure was enhanced from 84% to 92%. Finally, the remaining factor of external quantum efficiency for triple-junction solar cells was increased from 80% to 85.5%. [ABSTRACT FROM AUTHOR]

Published

2017

7. Photonic Structures for Light Trapping in Thin Film Silicon Solar Cells: Design and Experiment.

Author

Yi Ding, Peizhuan Chen, Qi Hua Fan, and Guofu Hou

Subjects

THIN films, PHOTONIC crystals, ZINC oxide

Abstract

One of the foremost challenges in designing thin-film silicon solar cells (TFSC) is devising efficient light-trapping schemes due to the short optical path length imposed by the thin absorber thickness. The strategy relies on a combination of a high-performance back reflector and an optimized texture surface, which are commonly used to reflect and scatter light effectively within the absorption layer, respectively. In this paper, highly promising light-trapping structures based on a photonic crystal (PC) for TFSCs were investigated via simulation and experiment. Firstly, a highly-reflective one-dimensional photonic crystal (1D-PC) was designed and fabricated. Then, two types of 1D-PC-based back reflectors (BRs) were proposed: Flat 1D-PC with random-textured aluminum-doped zinc oxide (AZO) or random-textured 1D-PC with AZO. These two newly-designed BRs demonstrated not only high reflectivity and sufficient conductivity, but also a strong light scattering property, which made them efficient candidates as the electrical contact and back reflector since the intrinsic losses due to the surface plasmon modes of the rough metal BRs can be avoided. Secondly, conical two-dimensional photonic crystal (2D-PC)-based BRs were investigated and optimized for amorphous a-SiGe:H solar cells. The maximal absorption value can be obtained with an aspect ratio of 1/2 and a period of 0.75 μm. To improve the full-spectral optical properties of solar cells, a periodically-modulated PC back reflector was proposed and experimentally demonstrated in the a-SiGe:H solar cell. This periodically-modulated PC back reflector, also called the quasi-crystal structure (QCS), consists of a large periodic conical PC and a randomly-textured Ag layer with a feature size of 500-1000 nm. The large periodic conical PC enables conformal growth of the layer, while the small feature size of Ag can further enhance the light scattering. In summary, a comprehensive study of the design, simulation and fabrication of 1D-PC- and 2D-PC-based back reflectors for TFSCs was carried out. Total absorption and device performance enhancement were achieved with the novel PC light-trapping systems because of their high reflectivity or high scattering property. Further research is necessary to illuminate the optimal structure design of PC-based back reflectors and high solar cell efficiency. [ABSTRACT FROM AUTHOR]

Published

2017

8. An efficient light trapping scheme based on textured conductive photonic crystal back reflector for performance improvement of amorphous silicon solar cells.

Author

Peizhuan Chen, Guofu Hou, QiHua Fan, Qian Huang, Jing Zhao, Jianjun Zhang, Jian Ni, Xiaodan Zhang, and Ying Zhao

Subjects

*PHOTONIC crystals, *AMORPHOUS silicon, *SOLAR cells, *ZINC oxide, *CURRENT density (Electromagnetism)

Abstract

An efficient light trapping scheme named as textured conductive photonic crystal (TCPC) has been proposed and then applied as a back-reflector (BR) in n-i-p hydrogenated amorphous silicon (a-Si:H) solar cell. This TCPC BR combined a flat one-dimensional photonic crystal and a randomly textured surface of chemically etched ZnO:Al. Total efficiency enhancement was obtained thanks to the sufficient conductivity, high reflectivity and strong light scattering of the TCPC BR. Unwanted intrinsic losses of surface plasmon modes are avoided. An initial efficiency of 9.66% for a-Si:H solar cell was obtained with short-circuit current density of 14.74 mA/cm², fill factor of 70.3%, and open-circuit voltage of 0.932 V. [ABSTRACT FROM AUTHOR]

Published

2014

9. Controllable light utilization in silicon-based thin film solar cells.

Author

Ying Zhao, Peizhuan Chen, Xiaodan Zhang, Ning Cai, Xinhua Geng, and Shaozhen Xiong

Published

2008

10. Application of metal nanowire networks on hydrogenated amorphous silicon thin film solar cells.

Author

Shouyi Xie, Guofu Hou, Peizhuan Chen, Baohua Jia, and Min Gu

Subjects

NANOWIRES, HYDROGENATED amorphous silicon, SOLAR cells

Abstract

We demonstrate the application of metal nanowire (NW) networks as a transparent electrode on hydrogenated amorphous Si (a-Si:H) solar cells. We first systematically investigate the optical performances of the metal NW networks on a-Si:H solar cells in different electrode configurations through numerical simulations to fully understand the mechanisms to guide the experiments. The theoretically optimized configuration is discovered to be metal NWs sandwiched between a 40 nm indium tin oxide (ITO) layer and a 20 nm ITO layer. The overall performances of the solar cells integrated with the metal NW networks are experimentally studied. It has been found the experimentally best performing NW integrated solar cell deviates from the theoretically predicated design due to the performance degradation induced by the fabrication complicity. A 6.7% efficiency enhancement was achieved for the solar cell with metal NW network integrated on top of a 60 nm thick ITO layer compared to the cell with only the ITO layer due to enhanced electrical conductivity by the metal NW network. [ABSTRACT FROM AUTHOR]

Published

2017