Your search keyword '"Tung Ting Yang"' showing total 10 results

1. Reference Architecture for Collaborative Design.

Author

Chin-Yin Huang, Tung-Ting Yang, Wu-Lin Chen, and Shimon Y. Nof

Published

2010

2. Photovoltaic characteristics of GaAs solar cells with selective filters

Author

Mu-Min Hung, Yu-Chen Lin, Tung-Ting Yang, Peichen Yu, Yi-Chin Wang, and Chung-Yu Hong

Subjects

Materials science, business.industry, Open-circuit voltage, Photovoltaic system, Energy conversion efficiency, Distributed Bragg reflector, law.invention, Optics, law, Optical cavity, Solar cell, Optoelectronics, Photonics, Optical filter, business

Abstract

Enhancing the photon recycling process in a solar cell can boost the open-circuit voltage (Voc). In this work, we employ a selective filter realized by alternative TiO2 and SiO2 dielectric layers with different cutoff wavelengths as the front surface structures, and a distributed Bragg reflector (DBR) grown by epitaxy on the rear side of GaAs solar cells to form an optical cavity. The idea is to suppress the radiative recombination emission loss at the material bandgap toward the front and rear side by increasing photon-recycling via a cavity design with minimal auxiliary impact on light current. From our experiment, when cut-off wavelength was designed at 840nm, the Voc of the cell increase by 1.1mV compared with the device without the selective filter. Moreover, we successfully developed an optical model that combines a rigorous couple wave analysis (RCWA) and photon recycling calculation NREL developed recently to quantify the Voc enhancement from different optical design on GaAs solar cells. Based on theoretical optimizations of the experimental data, if we can optimize the back DBR reflector or using metal as the back mirror, we can obtain a large Voc enhancement by 36.4mV using the selective filter with a cut-off wavelength of 840 nm. However, although we can use selective filter as top structure to improve the Voc, the power conversion efficiency is still limited due to the implementation of selective filters has affected light absorption at the desired spectral range. Nevertheless, this concept of light management may be further improved by using angular filters in order to prevent the loss of light current while improving the Voc and power conversion efficiency at the same time.

Published

2015

3. Compound biomimetic structures for efficiency enhancement of Ga₀.₅In₀.₅P/GaAs/Ge triple-junction solar cells

Author

Mu-Min, Hung, Hau-Vei, Han, Chung-Yu, Hong, Kuo-Hsuan, Hong, Tung-Ting, Yang, Peichen, Yu, Yu-Rue, Wu, Hong-Yih, Yeh, and Hong-Cheng, Huang

Abstract

Biomimetic nanostructures have shown to enhance the optical absorption of Ga₀.₅In₀.₅P/GaAs/Ge triple junction solar cells due to excellent antireflective (AR) properties that, however, are highly dependent on their geometric dimensions. In practice, it is challenging to control fabrication conditions which produce nanostructures in ideal periodic arrangements and with tapered side-wall profiles, leading to sacrificed AR properties and solar cell performance. In this work, we introduce compound biomimetic nanostructures created by depositing a layer of silicon dioxide (SiO₂) on top of titanium dioxide (TiO₂) nanostructures for triple junction solar cells. The device exhibits photogenerated current and power conversion efficiency that are enhanced by ~8.9% and ~6.4%, respectively, after deposition due to their improved antireflection characteristics. We further investigate and verify the optical properties of compound structures via a rigorous coupled wave analysis model. The additional SiO₂ layer not only improves the geometric profile, but also serves as a double-layer dielectric coating. It is concluded that the compound biomimetic nanostructures exhibit superior AR properties that are relatively insensitive to fabrication constraints. Therefore, the compound approach can be widely adopted for versatile optoelectronic devices and applications.

Published

2014

4. Impact of light management on photovoltaic characteristics of GaAs solar cells with photonic crystals and quasi-photonic crystals

Author

Peichen Yu, Mu Min Hung, Yi Chun Lai, Tung Ting Yang, and Martin D. B. Charlton

Subjects

Theory of solar cells, Photon, Materials science, business.industry, Open-circuit voltage, Photovoltaic system, Substrate (electronics), Gallium arsenide, chemistry.chemical_compound, chemistry, Optoelectronics, business, Photonic crystal, Voltage

Abstract

In detailed balance model, the efficiency of single-junction solar cells can be potentially as high as 33.5% under AM 1.5G illumination. However the best state-of-the-art devices are still far lower than those figures, even the electronic quality is nearly perfect. Therefore the efficiency gap should stem from the light management inside solar cells. Recently, external radiation efficiency (�� ext) derived from detailed balance model is emphasized to evaluate light management and photon recycling, which aggregates the loss of backward emission into substrate and non-radiative recombination. This factor can be highly relevant to the cell’s performance, especially open-circuit voltage (Voc), and maximizing Voc is generally considered as the last mile to approach ultra-high efficiency limit. In this work, we try to quantify the Voc enhancement in GaAs solar cells by enhancing light extraction. The simulation tools are RCWA simulation and photon recycling model NREL developed recently. The top structures we simulate here are TiO2 cones arranged in three PC/QPC lattices. After our calculation, the QPC 12-folds symmetry can make the biggest Voc enhancement 11.21meV compared with bare one, and the structure also possess extraordinary omni-directional anti-reflection ability for maintaining high Jsc. Our results also show that using this way to enhance Voc is especially suitable for cells with ordinary material quality. Therefore, the requests of ideal top structures for solar cells’ use are not only near-perfect anti-reflection, but the ability to maximize light extraction if no feature of angular filter exists.

Published

2014

5. Characteristics of conductive polymer/silicon heterojunction solar cells with periodic nanostructures

Author

Wei-Shen Weng, Martin D. Charlton, Yang-Yue Huang, Tung Ting Yang, Krishnan Chirenjeevi, Yi-Chun Lai, Riqui Chen, Peichen Yu, Hsin-Fei Meng, and Ward Pan

Subjects

Materials science, business.industry, Nanotechnology, Hybrid solar cell, Quantum dot solar cell, Polymer solar cell, law.invention, Monocrystalline silicon, law, Photovoltaics, Solar cell, Optoelectronics, Crystalline silicon, Plasmonic solar cell, business

Abstract

Mono- and multi-crystalline silicon photovoltaics currently still hold more than 80% market share because of the non-toxic, abundant material resources used, and their long-term stabilities. However, the cost of solar power is still more than three times that of fossil fuels, which necessitates a further reduction to accelerate its widespread use. It has been estimated that cell fabrication consumes 30% of the total manufacturing cost due to energy intensive semiconductor processes, such as high temperature furnace for doping, electrodes co-firing, high-vacuum chemical deposition, etc. Therefore, the organic-inorganic hybrid cell concept has been proposed to take advantage of the solution-based processes for rapid and low-cost production and the wide absorption spectrum of silicon. In this work, we demonstrate a hybrid heterojunction solar cell based on the structure of conductive polymer PEDOT:PSS spun cast on n-type crystalline silicon nanorod (SiNR) arrays with periodic arrangements. The nanorod arrays are fabricated by electron beam (E-beam) lithography followed by reactive-ion etching (RIE), which show capability to enhance light harvesting. In addition, SiNRs and PEDOT:PSS can form core-shell structure that provides a large p-n junction area for carrier separation and collection. We measured the optical and photovoltaic characteristics of these devices under a simulated class A solar simulator with a calibrated illumination intensity of 1000 W/m2 for the AM1.5G solar spectrum. A post-RIE damage removal etching (DRE) is subsequently introduced in order to mitigate the surface recombination issues and also alter the surface reflection due to modifications in the nanorod side-wall profile. Finally, we show that the DRE treatment can effectively recover the carrier lifetime and dark current-voltage characteristics of SiNRs hybrid solar cells to resemble the planar counterpart without RIE damages.

Published

2013

6. Towards high-efficiency triple-junction solar cells with bio-inspired nanostructures

Author

Tung Ting Yang, Hau-Vei Han, Y.-R. Wu, Gou Chung Chi, T.-G. Chen, K.-H. Hung, C.-Y. Hong, Peichen Yu, Mu Min Hung, and Y. L. Tsai

Subjects

Photocurrent, Materials science, Silicon, business.industry, Energy conversion efficiency, chemistry.chemical_element, law.invention, chemistry.chemical_compound, Nanolithography, Anti-reflective coating, Silicon nitride, chemistry, law, Optoelectronics, Nanosphere lithography, business, Lithography

Abstract

Triple-junction solar cells offer extremely high power conversion efficiency with minimal semiconductor material usage, and hence are promising for large-scale electricity generation. To fully exploit the broad absorption range, antireflective schemes based on biomimetic nanostructures become very appealing due to sub-wavelength scale features that can collectively function as a graded refractive index (GRIN) medium to photons. The structures are generally fabricated with a single-type dielectric material which guarantees both optical design robustness and mechanical durability under concentrated illumination. However, surface recombination and current matching issues arising from patterning still challenge the realization of biomimetic nanostructures on a few micrometer thick epitaxial layers for MJSCs. In this presentation, bio-inspired antireflective structures based on silicon nitride (SiN x ) and titanium dioxide (TiO 2 ) materials are demonstrated on monolithically grown Ga 0.5 In 0.5 P/In 0.01 Ga 0.99 As/Ge triple-junction solar cells. The nano-fabrication employs scalable polystyrene nanosphere lithography, followed by inductively-coupled-plasma reactive-ion-etching (ICP-RIE). We show that the fabricated devices exhibit omni-directional enhancement of photocurrent and power conversion efficiency, offering a viable solution to concentrated illumination with large angles of incidence. Moreover, a comprehensive design scheme is also presented to tailor the reflectance spectrum of sub-wavelength structures for maximum photocurrent output of tandem cells.

Published

2013

7. Antireflective scheme for InGaP/InGaAs/Ge triple junction solar cells based on TiO2 biomimetic structures

Author

Tung-Ting Yang, Ting-Gang Chen, Chung-Yu Hong, Kuo-Hsuan Hung, Peichen Yu, Yu-Rue Wu, and Guo-Chung Chi

Subjects

Materials science, Fabrication, business.industry, chemistry.chemical_element, Germanium, engineering.material, Gallium arsenide, law.invention, chemistry.chemical_compound, Reflection (mathematics), Anti-reflective coating, chemistry, Coating, law, Solar cell, engineering, Optoelectronics, business, Refractive index

Abstract

In this work, we demonstrate the device design, characterization, fabrication and analysis of biomimetic antireflective structures on III–V multi-junction solar cell. The cell without antireflective structure has a severe change of refractive index between the cell and air, causing a huge reflection (about 30%) and decrease the cell efficiency significantly. We can reduce light reflection by coating a proper material on the cell, diminishing the refractive index difference between cell and air interface. The optimization of single antireflection coating and biomimetic structure will be discussed and the experimental results will also be presented.

Published

2012

8. Impact of Light Management on Photovoltaic Characteristics of GaAs Solar Cells with Photonic Crystals and Quasi-Photonic Crystals.

Author

Yi-Chun Lai, Tung-Ting Yang, Peichen Yu, Mu-Min Hung, and Charlton, Martin

Published

2014

9. Reference Architecture for Collaborative Design

Author

Wu-Lin Chen, Shimon Y. Nof, Chin-Yin Huang, and Tung-Ting Yang

Subjects

Knowledge management, Scope (project management), Computer Networks and Communications, Process (engineering), business.industry, Computer science, Design collaboration, Computer Science Applications, Computational Theory and Mathematics, Reference architecture, Collaborative design, Product (category theory), Dimension (data warehouse), Architecture, Software engineering, business

Abstract

Issues and themes of Collaborative Design (CD) addressed by research done so far are so extensive that when running a project of collaborative design, people may lack directions or guidelines to support the whole picture. Hence, developing reference architecture for CD is important and necessary in the academic and the empirical fields. Reference architecture provides the systematic, elementary skeleton and can be extended and adapted to diverse, changing environments. It also provides a comprehensive framework and enables practices implemented more thoroughly and easily. The reference architecture developed in this re-search is formed along three dimensions: decision aspect, design stage, and collaboration scope. There are five elements in the dimension of decision aspect: (1) participant, (2) product, (3) process, (4) organization, and (5) information. The dimension of design stage includes three stages: (1) planning and concepting, (2) system-level design and detail design, and (3) testing and prototyping. The dimension of collaboration scope includes three types of collaboration: (1) cross-functional, (2) cross-company, and (3) cross-industry. Because of the three reference dimensions, a cubic architecture is developed. The cubic reference architecture helps decision-makers in dealing with implementing a CD project or activity. It also serves as a guideline for CD system developers or people involved in the design collaboration to figure out their own responsibility functions and their relations with other members. Demonstration of how to use the reference architecture in developing design collaboration activities and specifying the details for cross-company CD is also provided in this research.

Published

2010

10. Photovoltaic characteristics of GaAs solar cells with selective filters.

Author

Chung-Yu Hong, Mu-Min Hung, Tung-Ting Yang, Yi-Chin Wang, Yu-Chen Lin, and Peichen Yu

Published

2015