Search

Your search keyword '"Solar cells -- Materials"' showing total 38 results
Start Over Descriptor "Solar cells -- Materials" Search Limiters Full Text
38 results on '"Solar cells -- Materials"'

1. Harnessing Bio-based Materials in Solar Cells

Author

Montoya, Juliana

Subjects
Solar batteries -- Materials, Solar cells -- Materials, Cellulose fibers -- Testing, Nanocrystals -- Testing, Business, Chemicals, plastics and rubber industries, Chemistry
Abstract

Researchers are exploring the use of bio-based materials to enhance the performance and sustainability of solar cells. Bio-based materials can serve as both passive and active elements in solar cells. [...]

Published
2024

3. Planar perovskite solar cells with long-term stability using ionic liquid additives

Author

Bai, Sai, Da, Peimei, Li, Cheng, Wang, Zhiping, Yuan, Zhongcheng, Fu, Fan, and Kawecki, Maciej

Subjects
Perovskite -- Usage, Ionic liquids -- Usage, Solar batteries -- Materials, Solar cells -- Materials, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Solar cells based on metal halide perovskites are one of the most promising photovoltaic technologies.sup.1-4. Over the past few years, the long-term operational stability of such devices has been greatly improved by tuning the composition of the perovskites.sup.5-9, optimizing the interfaces within the device structures.sup.10-13, and using new encapsulation techniques.sup.14,15. However, further improvements are required in order to deliver a longer-lasting technology. Ion migration in the perovskite active layer--especially under illumination and heat--is arguably the most difficult aspect to mitigate.sup.16-18. Here we incorporate ionic liquids into the perovskite film and thence into positive-intrinsic-negative photovoltaic devices, increasing the device efficiency and markedly improving the long-term device stability. Specifically, we observe a degradation in performance of only around five per cent for the most stable encapsulated device under continuous simulated full-spectrum sunlight for more than 1,800 hours at 70 to 75 degrees Celsius, and estimate that the time required for the device to drop to eighty per cent of its peak performance is about 5,200 hours. Our demonstration of long-term operational, stable solar cells under intense conditions is a key step towards a reliable perovskite photovoltaic technology. Addition of an ionic liquid, BMIMBF.sub.4, to metal halide perovskite solar cells improves their efficiency and long-term operation under accelerated aging conditions of high temperature and full-spectrum sunlight., Author(s): Sai Bai [sup.1] [sup.2] , Peimei Da [sup.1] , Cheng Li [sup.3] [sup.8] , Zhiping Wang [sup.1] , Zhongcheng Yuan [sup.2] , Fan Fu [sup.4] , Maciej Kawecki [sup.5] [...]

Published
2019
Full Text
View/download PDF

4. Efficient planar heterojunction perovskite solar cells by vapour deposition

Author

Liu, Mingzhen, Johnston, Michael B., and Snaith, Henry J.

Subjects
Perovskite -- Properties -- Usage, Solar batteries -- Materials, Solar cells -- Materials, Nanotechnology -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Many different photovoltaic technologies are being developed for large-scale solar energy conversion (1-4). The wafer-based first generation photovoltaic devices1 have been followed by thin-film solid semiconductor absorber layers sandwiched between two charge-selective contacts (3) and nanostructured (or mesostructured) solar cells that rely on a distributed heterojunction to generate charge and to transport positive and negative charges in spatially separated phases (4-6). Although many materials have been used in nanostructured devices, the goal of attaining high-efficiency thin film solar cells in such a way has yet to be achieved (7). Organometal halide perovskites have recently emerged as a promising material for high-efficiency nanostructured devices (8-11). Here we show that nanostructuring is not necessary to achieve high efficiencies with this material: a simple planar heterojunction solar cell incorporating vapour-deposited perovskite as the absorbing layer can have solar-to-electrical power conversion efficiencies of over 15 per cent (as measured under simulated full sunlight). This demonstrates that perovskite absorbers can function at the highest efficiencies in simplified device architectures, without the need for complex nanostructures., Within a solar cell there are many different components with discrete roles and having different tolerances for purity and optoelectronic properties. The hybrid inorganic-organic solar cell concept is 'material agnostic' [...]

Published
2013

5. Impact of different Na-incorporating methods on Cu(In,Ga)[Se.sub.2] thin film solar cells with a low-Na substrate

Author

Ye, Shenglin, Tan, Xiaohui, Jiang, Minlin, Fan, Bin, Tang, Ken, and Zhuang, Songlin

Subjects
Dielectric films -- Optical properties, Dielectric films -- Composition, Thin films -- Optical properties, Thin films -- Composition, Semiconductors -- Optical properties, Semiconductors -- Composition, Solar batteries -- Materials, Solar batteries -- Optical properties, Solar batteries -- Composition, Solar cells -- Materials, Solar cells -- Optical properties, Solar cells -- Composition, Sodium -- Optical properties, Astronomy, Physics
Abstract

As a kind of Na-incorporating control method, NaF co-evaporation or soda-lime glass thin films (SLGTFs) are useful to improve the photovoltaic performance of Cu(In, Ga)[Se.sub.2] (CIGS) cells fabricated on low-Na substrates. X-ray diffraction (XRD) patterns and scanning electron microscope pictures demonstrate that the grain size of CIGS thin film is reduced with the addition of Na. In addition, a variance of the preferred orientation is found by XRD patterns in terms of SLGTF samples. By a use of 100 nm thick SLGTF as a Na source, the best CIGS solar cell with an efficiency of 13.42% has been obtained. [c] 2010 Optical Society of America OCIS codes: 160.6000, 310.6845.

Published
2010

6. An Interlaboratory Study on the Stability of All-Printable Hole Transport Material–Free Perovskite Solar Cells

Author

Francesca De Rossi, Artem Sadula, Luigi Angelo Castriotta, Eugene A. Katz, John Chircop, Jeff Kettle, Francesca Brunetti, Aldo Di Carlo, Vasil Stoichkov, Trystan Watson, Brian Azzopardi, Lucio Cinà, David M. Tanenbaum, Jérémy Barbé, Zhengfei Wei, Haibing Xie, Monica Lira-Cantu, and Wing C. Tsoi

Subjects
Materials science, Settore ING-INF/01, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, interlaboratory studies, perovskite solar cells, 01 natural sciences, 7. Clean energy, Solar cells -- Materials, Long-term stability, Perovskite (structure), Interlaboratory studies, Perovskite solar cells, carbon, Direct energy conversion, long-term stability, ISOS protocols, 021001 nanoscience & nanotechnology, Carbon, 0104 chemical sciences, General Energy, chemistry, Chemical engineering, 0210 nano-technology, Photovoltaic cells -- Materials
Abstract

Comparisons between different laboratories on long-term stability analyses of perovskite solar cells (PSCs) is still lacking in the literature. This work presents the results of an interlaboratory study conducted between five laboratories from four countries. Carbon-based PSCs are prepared by screen printing, encapsulated, and sent to different laboratories across Europe to assess their stability by the application of three ISOS aging protocols: (a) in the dark (ISOS-D), (b) under simulated sunlight (ISOS-L), and (c) outdoors (ISOS-O). Over 1000 h stability is reported for devices in the dark, both at room temperature and at 65 °C. Under continuous illumination at open circuit, cells survive only for few hours, although they recover after being stored in the dark. Better stability is observed for cells biased at maximum power point under illumination. Finally, devices operate in outdoors for 30 days, with minor degradation, in two different locations (Barcelona, Spain and Paola, Malta). The findings demonstrate that open-circuit conditions are too severe for stability assessment and that the diurnal variation of the photovoltaic parameters reveals performance to be strongly limited by the fill factor, in the central hours of the day, due to the high series resistance of the carbon electrode., peer-reviewed

Published
2020

7. Conjugated polymers: new materials for photovoltaics

Author

Wallace, Gordon G., Dastoor, Paul C., Officer, David L., and Too, Chee O.

Subjects
Polymers -- Usage, Semiconductors -- Materials, Solar cells -- Materials, Electrochemistry -- Research, Photochemical research -- Research, Aniline -- Usage, Solar energy -- Usage, Solar collectors -- Materials, Business, Chemicals, plastics and rubber industries, Chemistry, Engineering and manufacturing industries
Abstract

Conjugated polymers, which have alternating singe and double carbon-carbon, or sometimes carbon nitrogen, bonds, are new materials for photovoltaics. Polymers can act as semiconductors, with some effort on the part of chemists. Coatings might be able to do sunlight-harvesting on roofs or in fabrics. Resarch is in early stages, but results are encouraging. The best materials so far, using a polythiophene molecule as a hole-acceptor, have energy conversion efficiency of 7% when irradiated with green light. In sunlight it is about 2%. Excitons dissociate at interfaces of materials with different ionization energies and electron affinities after being produced in a conducting polymer. Topics include using induced charges, device configurations, poly(p-phenylenevinylenes), polyanilines, polythiophenes, high light-collection efficiency, and order at the molecular level.

Published
2000

8. Cap a la producció a gran escala de mòduls fotovoltaics orgànics semitransparents per a la seva integració en façanes d’edificis

Author

Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Lamaison Urioste, Rafael Martin, Aranda Carballo, Clara, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Lamaison Urioste, Rafael Martin, and Aranda Carballo, Clara

Abstract

L’energia solar fotovoltaica és una de les principals fonts renovables d’electricitat gràcies a la gran quantitat de recurs solar de què disposa la terra. Actualment, les tecnologies fotovoltaiques de silici cristal·lí dominen sobre la resta, amb una presència al mercat del 30% per als mòduls fotovoltaics de silici monocristal·lí i 60% per als de silici policristal·lí, però des de fa 30 anys noves generacions de fotovoltaiques han anat sorgint per fer front als principals desavantatges d’aquesta i, alhora, aportar nous atributs per a estendre el seu ús a altres aplicacions. La fotovoltaica orgànica és una tecnologia fotovoltaica de tercera generació particularment prometedora en aplicacions d’integració de mòduls fotovoltaics en elements constructius d’edificis, o BIPV (Building Integrated Photovoltaics), gràcies a les seves propietats de flexibilitat i transparència i el seu econòmic procés productiu mitjançant tècniques contínues de recobriment i impressió d’alt rendiment, baix consum energètic i amb capacitat de produir grans àrees. Amb aquests prospectes, s’han produït uns mòduls fotovoltaics orgànics semitransparents amb una capa activa basada en la heterojunció dels polímers P3HT i PCBM, dos elèctrodes transparents i un cristall fotònic per a maximitzar l’absorció de la irradiació solar. El treball inclou una anàlisi del procés productiu, del comportament elèctric i de la transparència dels mòduls. Alhora, s’efecuta l’extrapolació dels resultats a una futura producció a gran escala per determinar la viabilitat d’aquests mòduls en qüestió de costos, rendibilitat i efectes sobre el medi ambient. Tots aquests aspectes de la fotovoltaica orgànica son comparats amb la fotovoltaica convencional de silici cristal·lí. L'objectiu és que, en un futur no llunyà, la fotovoltaica orgànica pugui competir-hi en quota de mercat mitjançant la seva implantació i fidelització en una part d’aquest, potencialment molt extensa en utilitat i àrea, com són les façanes i altres elemen

Published
2017

9. Impact of TiO2 electron transport layer properties on planar Perovskite solar cells

Author

Horowitz, G., Gonzalez, J. P., Mercurio, Alessandro, Horowitz, G., Gonzalez, J. P., and Mercurio, Alessandro

Abstract

During the last century, the energy world consumption have been increasing exponentially due to the development of the societies. Furthermore, the evolution of technologies has gradually unbalanced the equilibrium between the production and the consumption of energy. This led to a tremendous deployment of the natural energy resources such as coal, oil and natural gas, without paying too much attention on possible consequences in terms of environmental effects. With the first oil shock in 1973, western countries started looking for new kind of energy sources, in order to limit the usage of oil and the dependence on exporter countries. Moreover, in the same period, new ideologies, like environmentalism, started to push up the attention toward a sustainable development. In this historical context, renewable energies seemed to be a good compromise to face these aspects. Among all the renewable technologies, photovoltaic solar cells are the most promising solution for a low-cost energy production. By the end of 2016 the total installed capacity amounted at least 303 GW corresponding to 1.8% of the global electricity demand. [1] Solar cells devices can be divided in three main categories: first generation solar cells are mainly based on crystalline silicon wafers (the second most abundant element in the Earth), with performances around 20%. This technology is dominating the market of the solar industry due to the good performances, high stability and strong reduction in cost. Silicon solar cells have a rigid structure that is sometimes considered as a drawback since they can not be used for flexible applications. The second generation solar cells use the thin-film technology and are mainly based on amorphous silicon, CIGS (copper, indium, gallium, selenium) and CdTe with typical efficiency from 14% up to 22% (CIGS). Important characteristics of these solar cells are the lower material consumption that means a reduction cost of the fabrication process, the lower temperatur

Published
2017

10. Impact of TiO2 electron transport layer properties on planar Perovskite solar cells

Author

Mercurio, Alessandro, Horowitz, G., and Gonzalez, J. P.

Subjects
Energies::Energia solar fotovoltaica [Àrees temàtiques de la UPC], Solar cells -- Materials, Cèl•lules solars -- Materials, Perovskita, Photovoltaic power generation, Perovskite, Energia solar fotovoltaica
Abstract

During the last century, the energy world consumption have been increasing exponentially due to the development of the societies. Furthermore, the evolution of technologies has gradually unbalanced the equilibrium between the production and the consumption of energy. This led to a tremendous deployment of the natural energy resources such as coal, oil and natural gas, without paying too much attention on possible consequences in terms of environmental effects. With the first oil shock in 1973, western countries started looking for new kind of energy sources, in order to limit the usage of oil and the dependence on exporter countries. Moreover, in the same period, new ideologies, like environmentalism, started to push up the attention toward a sustainable development. In this historical context, renewable energies seemed to be a good compromise to face these aspects. Among all the renewable technologies, photovoltaic solar cells are the most promising solution for a low-cost energy production. By the end of 2016 the total installed capacity amounted at least 303 GW corresponding to 1.8% of the global electricity demand. [1] Solar cells devices can be divided in three main categories: first generation solar cells are mainly based on crystalline silicon wafers (the second most abundant element in the Earth), with performances around 20%. This technology is dominating the market of the solar industry due to the good performances, high stability and strong reduction in cost. Silicon solar cells have a rigid structure that is sometimes considered as a drawback since they can not be used for flexible applications. The second generation solar cells use the thin-film technology and are mainly based on amorphous silicon, CIGS (copper, indium, gallium, selenium) and CdTe with typical efficiency from 14% up to 22% (CIGS). Important characteristics of these solar cells are the lower material consumption that means a reduction cost of the fabrication process, the lower temperature required during the process, and the possibility (thanks to their thickness) to fabricate them on a flexible substrate. Although the material used is less than in first generation cells, a large amount of energy is still needed during the fabrication process. Additionally, they are mainly based on non-abundant elements (CIGS) and toxic materials (CdTe) that limit their development, especially on the industrial scale. Third generation solar cells are considered being the most promising technologies for photovoltaic systems. They are developed with the purpose of reducing the cost of energy: for doing this, the objective is to increase the efficiency (multi-junction solar cell) and decrease the costs of material processing (organic solar cells). This group of technologies includes multi-junction solar cells (employing several layers of semiconductors in order to absorb the whole solar spectrum and to reduce thermalization) which hold the world record in terms of performances (fig. 1) and a variety of polymers and organic material-based solar cells. Recently, a new class of thin film solar cells, perovskite solar cells, has attracted the interest of researchers. In only few years since their first application in 2009 with an efficiency of 3%, PSCs showed huge potential, with a record efficiency of 22.1% (not stabilized) achieved in 2016 (fig. 1). [2] This work focuses on the growth of different TiO2 electron transport material on FTO substrates. The goal is to study the impact of TiO2 layer properties on the perovskite solar cells with planar structure, in order to respectively reduce the hysteresis and to improve the efficiency.

Published
2017

11. By molecular design

Author

Shao, Guosheng

Subjects
Solar energy industry -- Product development, Density functionals -- Usage, Density functionals -- Methods, Molecular structure -- Analysis, Titanium dioxide -- Analysis, Solar batteries -- Product development, Solar batteries -- Materials, Solar cells -- Product development, Solar cells -- Materials, Business, Chemicals, plastics and rubber industries
Abstract

UK's University of Bolton research team has been making an attempt to make a guide for effective doping formulation for titanium oxide phases. The team is using a molecular design approach within the framework of the density functional theory. Insights on their research are also given.

Published
2010

12. Cap a la producció a gran escala de mòduls fotovoltaics orgànics semitransparents per a la seva integració en façanes d’edificis

Author

Aranda Carballo, Clara, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, and Lamaison Urioste, Rafael Martin

Subjects
Semiconductors orgànics, Cèl·lules solars -- Disseny i construcció, Energies [Àrees temàtiques de la UPC], Solar cells -- Materials, Organic semiconductors, Cèl·lules solars -- Materials, Photovoltaic power generation, Solar cells -- Design and construction, Energia solar fotovoltaica
Abstract

L’energia solar fotovoltaica és una de les principals fonts renovables d’electricitat gràcies a la gran quantitat de recurs solar de què disposa la terra. Actualment, les tecnologies fotovoltaiques de silici cristal·lí dominen sobre la resta, amb una presència al mercat del 30% per als mòduls fotovoltaics de silici monocristal·lí i 60% per als de silici policristal·lí, però des de fa 30 anys noves generacions de fotovoltaiques han anat sorgint per fer front als principals desavantatges d’aquesta i, alhora, aportar nous atributs per a estendre el seu ús a altres aplicacions. La fotovoltaica orgànica és una tecnologia fotovoltaica de tercera generació particularment prometedora en aplicacions d’integració de mòduls fotovoltaics en elements constructius d’edificis, o BIPV (Building Integrated Photovoltaics), gràcies a les seves propietats de flexibilitat i transparència i el seu econòmic procés productiu mitjançant tècniques contínues de recobriment i impressió d’alt rendiment, baix consum energètic i amb capacitat de produir grans àrees. Amb aquests prospectes, s’han produït uns mòduls fotovoltaics orgànics semitransparents amb una capa activa basada en la heterojunció dels polímers P3HT i PCBM, dos elèctrodes transparents i un cristall fotònic per a maximitzar l’absorció de la irradiació solar. El treball inclou una anàlisi del procés productiu, del comportament elèctric i de la transparència dels mòduls. Alhora, s’efecuta l’extrapolació dels resultats a una futura producció a gran escala per determinar la viabilitat d’aquests mòduls en qüestió de costos, rendibilitat i efectes sobre el medi ambient. Tots aquests aspectes de la fotovoltaica orgànica son comparats amb la fotovoltaica convencional de silici cristal·lí. L'objectiu és que, en un futur no llunyà, la fotovoltaica orgànica pugui competir-hi en quota de mercat mitjançant la seva implantació i fidelització en una part d’aquest, potencialment molt extensa en utilitat i àrea, com són les façanes i altres elements d’edificis, en què els mòduls de silici cristal·lí no tenen cabuda per les seves propietats. Els principals reptes d’aquesta innovadora alternativa a la fotovoltaica convencional de silici cristal·lí són una millora en l’eficiència i, sobretot, en l’estabilitat, ja que la degradació és una gran contraindicació per a la seva integració en edificis.

Published
2017

13. Modelització de materials per a cel·les fotovoltaiques

Author

Esbert Pons, Lluc, Universitat de Girona. Facultat de Ciències, and Blancafort San José, Lluís

Subjects
Solar cells -- Materials, Photoelectric cells -- Materials, Cèl·lules solars -- Materials, Cèl·lules fotoelèctriques -- Materials
Abstract

At present there is an increase of the energy generated by means of renewable energies. One of the main sources of renewable energy is solar energy, which is produced by photovoltaic cells. One of the most recent types of photovoltaic cells is the organic photovoltaic cells (OPVs), which have interesting mechanical characteristics but have a relatively low yield The low performance of the OPVs is their main problem and to improve this performance one has to investigate and deeply understand the mechanism of the operation of these solar cells. In order to achieve this there is a problem that has to be prepared first, the material that compose the cell is amorphous and, therefore, it is difficult to investigate the structure experimentally. Since solving the structure is fundamental to learn how OPVs operate accurately then we will use computational methods per resolve the structure. The system to be studied consists of molecules p-DTS (FBTTh2) 2 and PC71BM. Since the molecules are very large It’s not possible simulate the system using a very precise quantum method because calculations would take too long, therefore we resort to force field methods that are faster but less accurate. In order for the results of the force field methods to be the closest to the results of the quantum methods, we will perform a parameterization. To do this parameterization we will divide the system into different parts: the molecule p-DTS(FBTTh2)2 will be divided into three fragments and the molecule PC71BM will be simplified to C70 fullerene. The parameterization itself will be based on parameterizating the rotation of the dihedral angles between the aromatic rings of the three fragments of the molecule p-DTS (FBTTh2)2, since this is the most flexible part of the fragments. It will also parameterize the stacking in the three fragments. Once the p-DTS(FBTTh2)2 molecule is parameterized, the C70 molecule will be parameterized. Specifically, only the stacking between two molecules of C70 fullerene will be parameterized

Published
2017

14. Crystal clear? Solar energy

Subjects
Solar energy -- Forecasts and trends, Solar cells -- Materials, Perovskite -- Properties -- Usage, Market trend/market analysis, Business, Economics, Business, international
Abstract

Perovskites may give silicon solar cells a run for their money ON THE desk of Chris Case, chief technology officer of Oxford Photovoltaics, there sits a small but heavy vial [...]

Published
2015

15. Investigating crystalline silicon cell-based solar photovoltaic module degradation in the Maltese climate

Author

Fenech, Carl, Yousif, Charles, Caruana, Cedric, and Sustainable Energy 2016 : the ISE Annual Conference

Subjects
Photovoltaic power systems -- Technological innovations -- Malta, Solar cells -- Materials, Solar cells -- Design and construction -- Malta
Abstract

Photovoltaic (PV) modules may experience degradation as soon as they are exposed to outdoor weathering conditions. This occurs from the early stages of installation up to the decommissioning stage. PV degradation exists in many forms, some of which occur during the first few months of exposure, while others depend on the materials’ susceptibility to continuous weathering. The Maltese climate is characterised by high levels of solar radiation, humidity and temperatures. These three factors together with coastal region conditions may affect the performance of the PV module during its lifetime. The aim of this research was to gain an understanding of the visual degradation modes together with the rate of loss in maximum power over a number of years of operation. PV modules operating over a range of one to twenty-eight years were analysed. This would provide a clear picture to the installers and investors on the expected degradation in power per year for warranty and energy yield purposes. The results showed that modules with more than eighteen years of operation experienced a greater degradation rate per year in maximum power, when compared to those up to fourteen years operating under Maltese climatic conditions. This implies that the newer modules use improved materials such as UV-stabilised encapsulation, protection against humidity ingress, among others., peer-reviewed

Published
2016

16. Nano solar cell integrated within optical nano resonator

Author

Maulidiani, Siti Winny Adya, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, and Voz Sánchez, Cristóbal

Subjects
Cèl·lules solars -- Disseny i construcció, Nanoestructures, Semiconductors, Solar cells -- Materials, Física::Física de l'estat sòlid::Semiconductors [Àrees temàtiques de la UPC], Energies::Energia solar fotovoltaica::Cèl·lules solars [Àrees temàtiques de la UPC], Cèl·lules solars -- Materials, Enginyeria dels materials [Àrees temàtiques de la UPC], Solar cells -- Design and construction, Nanostructures
Abstract

Photovoltaics have developed rapidly over a past decade. In the end of 2013, the total of solar PV global capacity reached 139 GW. The fast development of solar photovoltaic is mainly due to the improvement of solar cell efficiency and the decrease of the costs. The absolute cost of photovoltaic depends on the technology. The photovoltaic market is currently dominated by crystalline silicon. For crystalline silicon photovoltaic, the material cost represents 40% of the total module cost. On the other hand, the emerging technologies of photovoltaic require expensive and scarce materials. Hence, it is necessary to reduce the usage of raw materials in order to decline the cost of solar photovoltaic. One solution to save raw material is reducing the thickness of absorber solar cell. However, reducing the thickness of active layer could compromise the optical absorption. The main focus in this work is to develop nano solar cell integrated within optical nano resonator which is in the main frame of the PhD thesis work of Proise (Study and Realisation of Micro/Nano Photovoltaic Cells and Their Concentration Systems). Proise developed the simulation of the geometry of nano-resonator solar cell in order to optimise the absorber thickness while keeping a good absorption. Based on Proise’s result, the geometry of nanoresonator solar cell with a thickness of 350 nm, a width of 100 nm, and a period of 400 nm is decided to be fabricated. The semiconductor materials used in this work are based on III-V semiconductors, Indium Phosphide (InP) and InGaAs. InGaAs is expected to improve the ohmic contact between metal and InP since it has lower barrier height than InP. However, InGaAs can reduce the optical properties of nano-resonator solar cell since InGaAs can absorb the light. Therefore, the study of the contact resistance between metal and semiconductor and the influence of p-type InGaAs layer inserted between p-type InP and metal layer are performed in this work. The fabrication involves UV lithography and wet chemical etching. On the other hand, the characterization is conducted through transmission line measurement and micro-diode measurement. In this work, it is found that the InGaAs has an influence to reduce the series resistance of solar cell. As an ultimate goal in this work, the fabrication of nano solar cell integrated within optical nano resonator is performed. It involves the design of the mask for electron beam lithography, anodic bonding technique, electronic beam lithography, and dry etching. The results are observed through scanning electron microscopy. In this work, the geometry of nano-resonator solar cell has been developed successfully with a period of 400 nm.

Published
2014

17. CATCHING RAYS GETS CHEAPER

Author

Carey, John and Scott, Mark

Subjects
Company pricing policy, Market trend/market analysis, Solar batteries -- Production processes, Solar batteries -- Materials, Solar batteries -- Prices and rates, Solar cells -- Production processes, Solar cells -- Materials, Solar cells -- Prices and rates, Solar energy industry -- Production management, Solar energy industry -- Forecasts and trends
Published
2009

19. Organic solar cells gain ground -- For the full story, type the article ID after each item below into the search box at www.eetimes.com

Subjects
Solar energy industry -- Product development, Solar batteries -- Materials, Solar batteries -- Research, Solar cells -- Materials, Solar cells -- Research
Abstract

A new composite material for plastic solar cells, formulated at Ohio State University, offers what researchers there claim is the best bet yet for beating the relatively high cost of […]

Published
2007

20. Nano solar cell integrated within optical nano resonator

Author

Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Voz Sánchez, Cristóbal, Maulidiani, Siti Winny Adya, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Voz Sánchez, Cristóbal, and Maulidiani, Siti Winny Adya

Abstract

Photovoltaics have developed rapidly over a past decade. In the end of 2013, the total of solar PV global capacity reached 139 GW. The fast development of solar photovoltaic is mainly due to the improvement of solar cell efficiency and the decrease of the costs. The absolute cost of photovoltaic depends on the technology. The photovoltaic market is currently dominated by crystalline silicon. For crystalline silicon photovoltaic, the material cost represents 40% of the total module cost. On the other hand, the emerging technologies of photovoltaic require expensive and scarce materials. Hence, it is necessary to reduce the usage of raw materials in order to decline the cost of solar photovoltaic. One solution to save raw material is reducing the thickness of absorber solar cell. However, reducing the thickness of active layer could compromise the optical absorption. The main focus in this work is to develop nano solar cell integrated within optical nano resonator which is in the main frame of the PhD thesis work of Proise (Study and Realisation of Micro/Nano Photovoltaic Cells and Their Concentration Systems). Proise developed the simulation of the geometry of nano-resonator solar cell in order to optimise the absorber thickness while keeping a good absorption. Based on Proise’s result, the geometry of nanoresonator solar cell with a thickness of 350 nm, a width of 100 nm, and a period of 400 nm is decided to be fabricated. The semiconductor materials used in this work are based on III-V semiconductors, Indium Phosphide (InP) and InGaAs. InGaAs is expected to improve the ohmic contact between metal and InP since it has lower barrier height than InP. However, InGaAs can reduce the optical properties of nano-resonator solar cell since InGaAs can absorb the light. Therefore, the study of the contact resistance between metal and semiconductor and the influence of p-type InGaAs layer inserted between p-type InP and metal layer are performed in this work. The fabrication i

Published
2014

21. Another Dawn for Solar Power; Tech breakthroughs and high energy prices are rekindling the industry

Author

Port, Otis

Subjects
Market trend/market analysis, Solar energy industry -- Product development, Solar energy industry -- International aspects, Solar energy industry -- Capacity, Solar energy industry -- Industry forecasts, Solar cells -- Product information, Solar cells -- Materials, Solar cells -- International aspects, Solar cells -- Statistics, Solar batteries -- Product information, Solar batteries -- Materials, Solar batteries -- International aspects, Solar batteries -- Statistics, Solar energy -- Political aspects, Solar energy -- Forecasts and trends, Solar energy -- International aspects, Solar energy -- Statistics
Published
2004

22. Fabrication and Characterization of Small Molecule Organic Solar Cells

Author

Ayele Birhanu, Mulugeta, Puigdollers i González, Joaquim, and Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica

Subjects
Semiconductors orgànics, Cèl·lules solars -- Disseny i construcció, Organic semiconductors, Física::Física de l'estat sòlid::Semiconductors [Àrees temàtiques de la UPC], Energies::Energia solar fotovoltaica::Cèl·lules solars [Àrees temàtiques de la UPC], Cèl·lules solars -- Materials, Photovoltaic power generation, Solar cells -– Materials, Solar cells -- Design and construction, Energia solar fotovoltaica
Abstract

With increasing price of natural gas and petroleum products and their environmental concerns, alternative energy sources are required i.e. renewable energy sources. Solar energy is the abundant form of renewable energy. In addition to that, the total amount of solar power that incident on earth for an hour can cover the world’s annual electric power demand. Hence capturing even fraction of this abundant power source is vital. The technologies used to capture solar power are the photovoltaic systems which, through the photovoltaic effect in semiconductors in the solar cells comprising the system; convert the energy in the photons of the sunlight directly to electric power. The system with silicon solar cells has high production cost because of which it has been difficult for the system to be in to grid parity. The best alternative that attracted the attention of many researchers in the world is to use organic solar cells. Unlike their inorganic counterparts; the organic solar cells are easy and cheap to fabricate, light weighted, flexible, the semiconductors are tuneable with respect to their functions, colourful, can absorb light in cloudy days and semitransparent. The amount of semiconductor material required is very small (i.e. in 100nm). Because of these, even with half efficiency of inorganic ones can make them economical. The other advantage is that they can be used in areas where silicon solar cells haven’t been used and properties like light weightiness, flexibility and colourfulness are required. This could be in the sports, agriculture, medical sector …. However, they have disadvantages: low efficiency and shorter life span due to degradation of the semiconductors. Some of the factors that determine performance of solar cell are the type of structure used for the active layer of the solar cell and its thickness. The two kinds of structures we used in the lab were the bi-layer and bulk-junction photoactive layer. The performance of the bulk-junction solar cells increase with thickness of the photoactive layer up to certain point due to high intimacy of contact between the donor and acceptor and from this point on wards the performance decreases as recombination starts to dominate the effect of the intimacy of contact. Comparison of the bi-layer and bulk-junction solar cells for certain thickness tells that the bi-layer has higher fill factor and open circuit voltage than the bulk-junction due to relatively low recombination and density of states. The efficiency of organic solar cells is increasing at higher rate recently as researches have been taking place even in big named companies. The degradation of the organic semiconductors is due to oxygen and water valour from air which can be avoided by encapsulation of the solar cells.

Published
2013

23. Silicon Nanopillar Solar Cells Made by Near Field Phase-Shift Photolithography

Author

Canales Mundet, Ignasi and Fontcuberta Morral, Anna

Subjects
Photolithography, Silici -- Aplicacions industrials, Materials nanoestructurals, Solar cells -- Materials, Enginyeria dels materials::Materials funcionals::Materials elèctrics i electrònics [Àrees temàtiques de la UPC], Silicon -- Industrial applications, Cèl·lules solars -- Materials, Energies::Energia solar fotovoltaica::Centrals solars fotovoltaiques [Àrees temàtiques de la UPC], Photovoltaic power generation, Nanosilicon, Fotolitografia, Energia solar fotovoltaica
Abstract

A novel photolithographic technique which promises quick and easy large area patterning is explored to satisfy the nanowire applications requirements. Nanohole patterns for ordered nanowire growth and nanopillar arrays for PV applications are produced by means of Near Field Phase-Shift Photolithography. Furthermore, solar cells based on silicon nanopillars have been fabricated showing high e ciencies. The quality of di erent passivating materials was evaluated in this particular approach, concluding that a double layer of SiO2/SiNx is the most appropriate. Outgoing

Published
2012

24. Fabrication and Characterization of Small Molecule Organic Solar Cells

Author

Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Puigdollers i González, Joaquim, Ayele Birhanu, Mulugeta, Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica, Puigdollers i González, Joaquim, and Ayele Birhanu, Mulugeta

Abstract

With increasing price of natural gas and petroleum products and their environmental concerns, alternative energy sources are required i.e. renewable energy sources. Solar energy is the abundant form of renewable energy. In addition to that, the total amount of solar power that incident on earth for an hour can cover the world’s annual electric power demand. Hence capturing even fraction of this abundant power source is vital. The technologies used to capture solar power are the photovoltaic systems which, through the photovoltaic effect in semiconductors in the solar cells comprising the system; convert the energy in the photons of the sunlight directly to electric power. The system with silicon solar cells has high production cost because of which it has been difficult for the system to be in to grid parity. The best alternative that attracted the attention of many researchers in the world is to use organic solar cells. Unlike their inorganic counterparts; the organic solar cells are easy and cheap to fabricate, light weighted, flexible, the semiconductors are tuneable with respect to their functions, colourful, can absorb light in cloudy days and semitransparent. The amount of semiconductor material required is very small (i.e. in 100nm). Because of these, even with half efficiency of inorganic ones can make them economical. The other advantage is that they can be used in areas where silicon solar cells haven’t been used and properties like light weightiness, flexibility and colourfulness are required. This could be in the sports, agriculture, medical sector …. However, they have disadvantages: low efficiency and shorter life span due to degradation of the semiconductors. Some of the factors that determine performance of solar cell are the type of structure used for the active layer of the solar cell and its thickness. The two kinds of structures we used in the lab were the bi-layer and bulk-junction photoactive layer. The performance of the bulk-junction solar ce

Published
2013

25. Capas de CulnSe2 para células solares: análisis por espectroscopia Raman de capas pobres en Cu

Author

Arias Montenegro, Francisco Javier, Pérez, Alejandro, and Universitat Politècnica de Catalunya. Departament de Ciència dels Materials i Enginyeria Metal·lúrgica

Subjects
Enginyeria dels materials::Metal·lúrgia [Àrees temàtiques de la UPC], Coure, Solar cells -- Materials, Energies::Energia solar fotovoltaica::Cèl·lules solars [Àrees temàtiques de la UPC], Cèl·lules solars -- Materials, Spectrum Analysis, Raman, Copper, Espectroscòpia Raman
Abstract

En este trabajo se presenta un estudio mediante espectroscopía Raman de capas CuInSe2 sintetizadas en condiciones de defecto de Cu, en función de su composición. El interés del estudio viene motivado por el potencial de este material como capa absorbedora para células solares de alta eficiencia y bajo coste. En el estado actual de la tecnología, estas capas se sintetizan en condiciones de defecto de Cu para evitar la formación de fases secundarias Cu-Se. En una primera parte, se han analizado las condiciones experimentales idóneas para las medidas Raman, lo que ha implicado un estudio de la presencia de efectos de potencia en los espectros. Se han analizado capas con diferentes relaciones Cu/In. La interpretación de los espectros permite deducir la coexistencia en las capas de fases desordenadas con vacantes (OVC) junto con la fase calcopirita, lo que ha sido corroborado mediante medidas de XRD. Las medidas han permitido fijar el rango de composiciones en que se produce la coexistencia de estas fases. El proyecto cuenta con la colaboración del centro de investigación "ZSW: Zentrum für Sonnenergie und Wasserstoff-Forshung, Baden-Württemberg", en el marco de un proyecto europeo en que participa el Dept. de Electrónica de la Universidad de Barcelona.

Published
2009

26. Silicon Nanopillar Solar Cells Made by Near Field Phase-Shift Photolithography

Author

Fontcuberta Morral, Anna, Canales Mundet, Ignasi, Fontcuberta Morral, Anna, and Canales Mundet, Ignasi

Abstract

A novel photolithographic technique which promises quick and easy large area patterning is explored to satisfy the nanowire applications requirements. Nanohole patterns for ordered nanowire growth and nanopillar arrays for PV applications are produced by means of Near Field Phase-Shift Photolithography. Furthermore, solar cells based on silicon nanopillars have been fabricated showing high e ciencies. The quality of di erent passivating materials was evaluated in this particular approach, concluding that a double layer of SiO2/SiNx is the most appropriate., Outgoing

Published
2012

27. Capas de CulnSe2 para células solares: análisis por espectroscopia Raman de capas pobres en Cu

Author

Universitat Politècnica de Catalunya. Departament de Ciència dels Materials i Enginyeria Metal·lúrgica, Pérez, Alejandro, Arias Montenegro, Francisco Javier, Universitat Politècnica de Catalunya. Departament de Ciència dels Materials i Enginyeria Metal·lúrgica, Pérez, Alejandro, and Arias Montenegro, Francisco Javier

Abstract

En este trabajo se presenta un estudio mediante espectroscopía Raman de capas CuInSe2 sintetizadas en condiciones de defecto de Cu, en función de su composición. El interés del estudio viene motivado por el potencial de este material como capa absorbedora para células solares de alta eficiencia y bajo coste. En el estado actual de la tecnología, estas capas se sintetizan en condiciones de defecto de Cu para evitar la formación de fases secundarias Cu-Se. En una primera parte, se han analizado las condiciones experimentales idóneas para las medidas Raman, lo que ha implicado un estudio de la presencia de efectos de potencia en los espectros. Se han analizado capas con diferentes relaciones Cu/In. La interpretación de los espectros permite deducir la coexistencia en las capas de fases desordenadas con vacantes (OVC) junto con la fase calcopirita, lo que ha sido corroborado mediante medidas de XRD. Las medidas han permitido fijar el rango de composiciones en que se produce la coexistencia de estas fases. El proyecto cuenta con la colaboración del centro de investigación "ZSW: Zentrum für Sonnenergie und Wasserstoff-Forshung, Baden-Württemberg", en el marco de un proyecto europeo en que participa el Dept. de Electrónica de la Universidad de Barcelona.

Published
2009

28. Electronic and optical characterisations of silicon quantum dots and its applications in solar cells

Author

Fangsuwannarak, Thipwan, Photovoltaics & Renewable Energy Engineering, Faculty of Engineering, UNSW and Fangsuwannarak, Thipwan, Photovoltaics & Renewable Energy Engineering, Faculty of Engineering, UNSW

Abstract

In this thesis, the structural, optical and electrical properties of crystalline silicon quantum dots (SiQDs) are examined for application to silicon based tandem cells. The approach has been to concentrate on all silicon devices by taking advantage of quantum confinement in low-dimensional Si. RF magnetron co-sputtering provided the capability of creating superlattice structures in conjunction with high temperature annealing, to form Si nanocrystals in an oxide matrix. Structural techniques, including Fourier transform infrared spectroscopy (FTIR), micro-Raman spectroscopy, transmission electron microscopy (TEM), X-ray diffraction (XRD), and Secondary ion mass spectroscopy (SIM) were employed to gather structural information about the SiQD/SiO2 SLs. The result combine presents that the packing density of Si QDs, correlated to the oxygen content of the silicon rich oxide layer can be control independently.The effect of Si nanocrystallite density on Raman scattering is investigated. The preliminary results present that a decrease in the oxygen content (x) results in an increased sharpness of the Strokes-mode peak of nanocrystalline Si, attributed to an increase in the proportion of crystalline Si because of the increased number of SiQDs. However the influence of the surface region on the crystallite core intensity scattering becomes dominant, when SiQD size diameter is very small (less than 3 nm). The present work shows that a decrease in x-content leading to an increase of the SiQD concentration, initially results in the enhancement of the lateral conductivity in the SiQD superlattice material.In this work, the Al contacting scheme, using a prolonged heat treatment technique at elevated temperature less than the eutectic point of Al and Si (577C) has been successfully applied to making Ohmic contacts on both SiQD SLs in oxide and nitride matrices. Activation energy (Ea) of SiQDs, extracted from a linear Arrhenius plot is investigated in the present work in order to

Published
2007

29. The pitfalls of pit contacts: electroless metallization for c-Si solar cells

Author

Fisher, Kate, Photovoltaics & Renewable Energy Engineering, Faculty of Engineering, UNSW and Fisher, Kate, Photovoltaics & Renewable Energy Engineering, Faculty of Engineering, UNSW

Abstract

This thesis focuses on improving the adhesion of electroless metal layers plated to pit contacts in interdigitated, backside buried contact (IBBC) solar cells. In an electrolessly plated, pit contact IBBC cell, the contact grooves are replaced with lines of pits which are interconnected by the plated metal. It is shown, however, that electroless metal layers, plated by the standard IBBC plating sequence, are not adherent on pit contact IBBC solar cells. The cause of this adhesion problem is investigated by examining the adhesive properties of each of themetal layers in the electroless metallization sequence on planar test structures. This investigation reveals that Pd activation of heavily P diffused Si impedes Ni silicide growth and that, in the absence of a silicide at the Ni/Si interface, an electrolessly plated Cu layer will cause the underlying Ni layer to peel away from the substrate. It is also found that the Ni silicidation process itself intermittently causes the unreacted Ni to spontaneously peel away from the substrate. An electroless metallization sequence that results in thick, adhesive Cu deposits on planar &lt 100&gt surfaces is developed in this thesis. It is shown that this process leads to the formation of a Ni silicide on both n- and p- type, heavily diffused surfaces. Fully plated, pit contact IBBC solar cells were not able to be fabricated during the course of this work but it is reasonable to expect that the modified plating sequence developed in this work will result in the metal layers being adhesive on these cells.

Published
2007

34. Practical plastic solar cells: new dyes and electrolytes improve efficiency of Gratzel cells

Subjects
Electrolytes -- Properties, Dyes and dyeing -- Properties, Solar batteries -- Materials, Solar cells -- Materials
Abstract

SOURCE: 'NEW EFFICIENCY RECORDS FOR STABLE DYESENSITIZED SOLAR CELLS WITH LOW-VOLATILITY AND IONIC LIQUID ELECTROLYTES' Michael Gratzel et al. Journal of Physical Chemistry C 112: 17046-17050 Results: Scientists at the […]

Published
2009

35. Moisture barrier for solar cells

Author

Ellis, Meagan

Subjects
Dielectric films -- Product information, Thin films -- Product information, Solar batteries -- Materials, Solar cells -- Materials, Nanotechnology -- Research, Business, Chemicals, plastics and rubber industries
Published
2008

36. Solar energy without subsidies?

Author

Schanssema, Aafko

Subjects
Solar batteries -- Materials, Solar cells -- Materials, Conducting polymers -- Chemical properties, Conducting polymers -- Environmental aspects, Plastics -- Environmental aspects, Plastics -- Chemical properties, Alternative energy sources -- Research, Alternative energy sources -- Materials, Business, Chemicals, plastics and rubber industries
Published
2008

37. Giving solar cells the rough treatment. (Technology)

Subjects
Solar batteries -- Materials, Solar cells -- Materials, Science and technology, Materials
Abstract

Researchers in Germany have modified standard solar cell designs so that they can be made from cheaper materials. That could be important, because price has long been a major obstacle [...]

Published
2003

38. Lower silicon costs for solar cells

Author

Houlder, Vanessa

Subjects
Solar cells -- Materials, Banking, finance and accounting industries, Business, Business, international, Fraunhofer Institute for Solar Energy Systems -- Research
Published
1997

Catalog

Books, media, physical & digital resources
See catalog results