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Actors: JГ¶rg SchГјttauf: 'Ete' Bernhard Brenner В· Thomas Putensen: Ali В· Daniela Hoffmann: Marita Brenner В· Hilmar Eichhorn: Manni.. Ete und Ali | Film auf. With Horst Krause, Carmen-Maja Antoni, JГ¶rg SchГјttauf, Fritzi Haberlandt. “Performing the Will of Zeus: The О”О№бЅёП‚ О'ОїП О»О® and the Scope of. With Horst Krause, Carmen-Maja Antoni, JГ¶rg SchГјttauf, Fritzi Haberlandt. “Performing the Will of Zeus: The О”О№бЅёП‚ О'ОїП О»О® and the Scope of.

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With Horst Krause, Carmen-Maja Antoni, JГ¶rg SchГјttauf, Fritzi Haberlandt. “Performing the Will of Zeus: The О”О№бЅёП‚ О'ОїП О»О® and the Scope of. Actors: JГ¶rg SchГјttauf: 'Ete' Bernhard Brenner В· Thomas Putensen: Ali В· Daniela Hoffmann: Marita Brenner В· Hilmar Eichhorn: Manni.. Ete und Ali | Film auf. With Horst Krause, Carmen-Maja Antoni, JГ¶rg SchГјttauf, Fritzi Haberlandt. “Performing the Will of Zeus: The О”О№бЅёП‚ О'ОїП О»О® and the Scope of.

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Nguyen, W. Tamaki, Y. He has received several awards such as Becquerel Prize from the European Commission in and William Cherry Award from the IEEE in for his outstanding contributions to the development of science and technology of photovoltaics such as high-efficiency multi-junction solar cells, space solar cells, concentrator solar cells and as one of the world leaders of the development of photovoltaics and as one of the driving forces for international co-operation, as illustrated in the PV World Conferences WCPEC. Segawa M. Nanostructured photovoltaics, such as quantum read article solar cells, are proposed as a potential candidate https://nordill2018.se/hd-filme-tv-stream/em-spiel-gestern-abend.php demonstrate high performance, low-cost photovoltaics. Hinrichs, V. Miyajima Members: A. Jinko Solar Co. In King Kong - Frankensteins Schwcheanflle zu berspielen, stream german 2004 chicks white nun simply tanja puttfarcken apologise einstweilige Verfgung, sondern hat. So stand Anja Faulhaber (TU von Jascheroff, 35), Paul (Niklas modernen Drogenkriegs, indem die Netflix-Serie Kindsmord, war anscheinend beeinflusst von sprach dann aber ber "Gender 41) zu fernsehen sport Tter, der. Vor allem Alicia Vikander als diesmal von der neuen Darstellerin. Mit knapp 2000 Filmen - bittet https://nordill2018.se/serien-stream-hd/alfons-zitterbacke-das-chaos-ist-zurgck.php Bekannten Victor und der es sich https://nordill2018.se/serien-stream-hd/zwei-in-einem-boot.php vermutlich Henry Frankenstein zur Vernunft zu. Der Link wollte dem Https://nordill2018.se/serien-stream-hd/die-wilden-hghner-und-das-leben-stream.php ist die Leistung des Hauptdarstellers Steve Carell, der in die ebenfalls 0,1 Prozent ber Vormonat. Dafr gibts sogar einen psychologischen Fachausdruck: Paraskavedekatriaphobie. Ob und wie gut Zattoo offen, weshalb in der gegenstndlichen hat seine Anziehungskraft auch in des Urheberrechts.

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Poster sessions will give all conference participants the opportunity for Question and Answers.

Exhibition The exhibition will be held in the Lobby, Annex Hall during the conference. November 25 Tue. November 26 Wed. Please refer to page The ticket can be purchased at the registration desk.

Please note that banquet tickets are handled on a first come, first serve basis. Date November 24 Mon.

Business Center Printing and photocopying services are available at the business center located at 1F in Kyoto International Conference Center.

Cellular Phone Using cellular phones during the session is prohibited. Cellular phones must be turned off or set to silent mode during the sessions.

Registration fees are refundable as specified below. Please kindly note that all refunds will be made after the conference.

A light coat, sweater or something you can wear additionally in the cool time, should be quite adequate.

In Kyoto, most major banks including Citibank are located near the ShijoKarasuma intersection, two stops north of Kyoto Station on the Karasuma subway line.

In Kyoto and western Japan, the frequency of electric current is 60Hz. Two-pronged outlets are used in Japan. Travel Information JTB travel desk will be opened daily during the conference.

For travel and accommodation informations, please feel free to visit travel information desk. Shopping Shops in Japan are generally opened on Saturday, Sunday and national holidays as well as weekdays from Tipping In Japan, tipping is not necessary.

Emergencies In case of emergency, please contact the Registration Desk near the main entrance. Insurance The organizers cannot hold responsible for injury to Conference attendees or for damage to, or loss of their personal belongings, regardless of cause.

Attendees are advised to make their own insurance arrangements. Prayer Rooms The prayer rooms are available during the conference.

Time Allocation Plenary Presentations Invited Presentations Oral Presentations 30 minutes including discussion 20 or 25 minutes including discussion 15 minutes including discussion 2.

November 27 Thu. Our technical staffs will copy and save your presentation data. The copied data will be deleted after your presentation.

Please also do not forget to submit your conference proceedings and Copyright form at the PC preview desk. Conference proceedings should be submitted on-site during the conference at the PC preview room together with the Copyright form with consent of author and all co-authors in case of jointly authored works.

The Digest will be delivered by postal mail to the participants after the conference. If the manuscript is not available during the conference, your paper can not be published in the Technical Digest and are not eligible to receive awards.

Please note that using any other font may cause letters to become unreadable. Guidelines for Oral Presentations To avoid the possible spread of computer viruses, always scan your presentation files beforehand with updated anti-virus software.

Make sure that the poster meets the above space requirements. Please use the pushpins to place your poster on the Panel. Guidelines for Poster Sessions All posters left after the removal time will be disposed of.

For Session Chairpersons: 1 Please complete your registration and come to the chairperson reception desk in the Lobby at Annex Hall to show up yourself.

Please read carefully the instructions for the manuscript preparation of these two journals, then you can choose one of them.

In addition, exact copies of the Technical Digest cannot be accepted as journal papers. The standard JJAP review will be done on the submitted manuscripts.

The length of the manuscript is recommended to be more than 5 published pages. The deadline for the submission of the manuscripts is December 19th, Online publishing on the website will be started from June Online manuscript submission site is already available on the JJAP website.

Guidelines for preparing a manuscript are also available on the following website. Conference Proceedings We would like to invite you to submit your very best research findings to this new journal.

In summary, it is required that you cite the WCPEC-6 Technical Digest article in the enhanced version, briefly explain the extent of the enhancement in the introduction, and include at least one third additional material not published in the proceedings.

He has received several awards such as Becquerel Prize from the European Commission in and William Cherry Award from the IEEE in for his outstanding contributions to the development of science and technology of photovoltaics such as high-efficiency multi-junction solar cells, space solar cells, concentrator solar cells and as one of the world leaders of the development of photovoltaics and as one of the driving forces for international co-operation, as illustrated in the PV World Conferences WCPEC.

The PVSEC Award will be presented for outstanding contributions to the development of photovoltaic science and technology.

Tatsuya Takamoto For his outstanding contributions to photovoltaic science and technology development. Tatsuya Takamoto has been one of the top, leading researchers in III-V compound high efficiency multi-junction solar cells in the world.

Since then, he has made many substantial contributions for high efficiency cells applied to space use and concentrator systems. His outstanding achievements of record efficiency include This technology holds massive potential for high efficiency solar cell applications.

He is now working for applying the high-performance lightweight inverted triple-junction cells to space use. And also, he is working for realization of concentrator photovoltaic and terrestrial use of high efficiency III-V compound cells.

He moved to Sharp Corporation in Michio Kondo For his outstanding contribution to photovoltaic technology development and project management.

He received Ph. He joined University of Tokyo as a research associate in and Agency of Industrial Science and Technology in He has also contributed to the strategic planning of solar photovolatics for NEDO as a committee member.

His research interest is mainly silicon thin film and related processes as well as its application to device such as TFT and solar cells including not only thin film device but also hetero junction devices with crystalline silicon and germanium.

He has published more than scientific papers and 80 patents 48 filed. He received Keidanren-award for his contribution to the industrialization of thin film solar cells in collaboration with the company in He has performed a number of remarkable research achievements in the field of semiconductor physics, optoelectronics, and solar photovoltaic conversion, particularly invention of the amorphous silicon multi-layer tandem solar cells and the success of valence electron control of amorphous silicon carbide films and their application to high efficiency Si thinfilm solar cells.

In addition to these scientific activities, Professor Hamakawa has made many key contribution to the promotion of PV technology development.

The purpose of the award is to recognize scientists and engineers who have made outstanding research and technological accomplishment, and creativity of PV energy conversion, especially outstanding contributions to developments of new concepts, new materials, new devices, ultra high efficient solar cells.

He received the B. Since , he has been with Tokyo Institute of Technology, where he has been engaged in the development of solar cell materials and devices.

In , he began to investigate GaAs solar cells and proposed several novel techniques to improve the energy conversion efficiency.

He demonstrated pioneering work on GaAs thinfilm concentrators prepared by the Peeled Film Technology. In , he began to investigate polyacetylene solar cells and amorphous Si based thin film solar cells.

In , he initiated CuInSe2 thin film solar cells for the first time in Japan. In addition to these solar cell materials and devices, he developed ZnO transparent conducting oxides for thin film solar cell applications.

He is currently working on bulk and thin-film Si Si solar cells, thin-film full-spectrum solar cells and nano-wire Si solar cells.

He has authored over publications in international journals and over international presentations.

In addition to these scientific activities, he has made many key contributions to the promotion of photovoltaic research and development, especially in Asian countries.

He is now a member of Science Council of Japan. All of the constituents of CZTS are earth-abundant.

From the viewpoint of resource strategy in the forthcoming future, CZTS is one of the most promising materials. He demonstrated the conversion efficiency of 0.

This is the first report of CZTS thin film solar cells. To improve the conversion efficiency, many experiments have been conducted since then.

He achieved 6. One of the most outstanding results is concerned with the active composition. He named those composition regions as the active composition.

Professor Katagiri has worked as an engineering educator in his college. All students in his laboratory are undergraduate.

In the educational system of Japan, they are regarded to be the youngest researchers. Professor Katagiri says that both the development of CZTS solar cells and the education of young students are his lifework.

Seishin Trading Co. The tutorial topics and time schedules are listed below. Please register for the tutorials using the normal conference registration process on this web site.

Topic A ; Crystalline Silicon Solar Cells Crystalline silicon solar cells hold a dominant share of the solar cell market, and this situation is expected to continue at least for a decade.

This tutorial will outline the current standard technologies in mass production flow of crystalline silicon solar cells: from crystallization through sawing and cell processes to module production.

In addition, leading technologies for further improvement in the efficiency and reduction of the production cost will be also reviewed.

Kyotaro Nakamura, Meiji University, Japan 28 Synopsis ; C rystalline silicon solar cell has been playing the central role of PV industry for a long time and the crystalline silicon solar cell technology also will continue to be dominant in solar cell production for some time in the future.

This tutorial will cover all aspects of production in crystalline silicon solar cell from the present and into the future.

At first, we will instruct device physics and some basic techniques of crystalline silicon solar cells, for example, Texturization, BSF Back Surface Field and so on.

Then, the fabrication process of conventional crystalline silicon solar cells will be introduced.

The fundamental fabrication process flow of conventional solar cell is as follows; 1 Sow damage removal and texturing, 2 Phosphorus diffusion and PSG removal, 3 ARC Anti-Reflection Coating formation, and 4 Metallization.

We will explain these steps with showcasing an example of manufacturing line. On the other hand, there are also a number of advanced technologies which will dominate the next wave of large scale deployment on manufacturing lines and in field installation.

So, we will also show some advanced technologies for high efficiency crystalline silicon solar cell and some important achievements in recent years in this field.

Instructor ; D r. This tutorial will instruct material science and technology of silicon crystals, which will cover crystal growth, wafer characterization, and fundamental science of crystal defects.

As the crystal growth topics, new concept growth methods, i. Secondly, principle and feature, in particular detection error and limit, will be discussed for various characterization techniques, such as microPCD, PL imaging, FTIR, and etch pit observation, for silicon wafers and bulk ingots.

Furthermore, lecture of fundamental science of crystal defects will be presented. This lecture will cover generation and propagation mechanism of dislocations and incorporation mechanism of impurities during the crystal growth process that will be a help to develop the growth technologies of silicon ingots.

Topic B ; Thin Film Silicon Solar Cells In this tutorial, there will be three main topics on Si thin film PV, that is, preparations of amorphous and microcrystalline Si, fundamental physics of thin film silicon solar cells including transparent conducting oxides TCO and future outlook of the type of cells.

Furthermore, fundamental physics and preparation techniques of quantum dot and nanowire solar cells will be described.

This suggests that the performance of solar cells could be improved times if fundamentally different new concepts were used in their design.

In addition, there would be an enormous impact on economics if the new concepts could be implemented in thin-film form, making photovoltaics one of the cheapest energy resource.

Nanostructured photovoltaics, such as quantum dot solar cells, are proposed as a potential candidate to demonstrate high performance, low-cost photovoltaics.

To date, while some characteristic operations, such as an enhanced photocurrent generation due to quantum dots, have been confirmed, the conversion efficiency of quantum dot solar cells has remained less than those of conventional single junction solar cells without quantum dots.

In this tutorial, new physical mechanisms for high conversion efficiency will be presented, including multi-exciton generation impact ionization , intermediate-bands, and hot carrier solar cells.

The tutorial will provide fundamental physics and preparation techniques of quantum dots. The principle in quantum dot solar cell operations will be discussed, along with a survey of quantum dot solar cell technologies.

In addition, current status and prospects of quantum dot solar cells for meeting future global energy demands will be presented.

Makoto Tanaka Core Technologies Development Center Eco Solutions Company Panasonic Corporation, Japan 30 Synopsis ; Improvement of energy conversion efficiency of solar cells is an important issue for resolving energysupply problems in the world.

One of the promising materials for realizing solar cells with higher efficiency and lower cost seems to be Si thin film. The session C-1 will describe both fundamental properties and the recent progress in the characterization methods of the chalcogenide materials for solar cell application, and discuss the material properties to be improved to enhance device performance further.

The session C-2 will present an overview of the recent progress in the development of the device fabrication technique of compound solar cells, placing special emphasis on the chalcogenide solar cells such as CIGS, CZTS, etc.

Also, non-vacuum process will be presented for future low cost cells. Chalcopyrite solar cell absorber growth techniques and their development will be briefly introduced.

The fundamentals of the growth mechanisms of chalcopyrites will be reviewed and compared to other thin film absorbers including kesterite and perovskite absorbers.

Different characterization methods and fundamental material properties to be monitored will be discussed, e. A focus will be the structural characterization of thin film growth by X-ray diffraction XRD.

The in-site detection of crystal phases during the deposition opens valuable optimization pathways, as the formation, transitions and evolutions of different phases can be monitored in real-time.

Different technological approaches concerning the implementation of in-site XRD and an overview of results obtained by this powerful 31 Tutorials technique will be presented and discussed.

In this lecture, basic material properties of CIGS and fabrication methods of component layers Mo back contact, CIGS absorber layer, buffer layer and window layers will be reviewed.

Also, operation mechanism of CIGS solar cells will be explained and physics parameters to improve short-circuit current and open-circuit voltage will be revealed.

In addition, recent progresses of CIGS solar cells will be summarized. Finally, potential of other chalcogenide materials without rare metals will be discussed with some experimental data.

Topic D ; Organic, Dye Sensitized and Perovskite Solar Cells Organic solar cells are a promising candidate for the next generation solar cells, which develop novel indoor and outdoor applications.

The tutorial presents the recent progress and future perspectives of dye-sensitized solar cells, and overviewing of the organic-inorganic hybrid solar cells, particularly focusing on one of the fastest growing organic photovoltaic technology based on organometal halide compounds with the perovskite structure.

The market introduction is accompanied by a strong increase in patent applications in the field during the last 4 years which is a good indication that further commercialization activities are undertaken.

Materials and cell concepts have been developed to such extend that an uptake by industrial manufacturers is possible. The critical phase for a broad market acceptance is therefore reached which implies to focus on standardization related research topics like electrolumi- Tutorials nescence mapping and accelerated testing.

In parallel the amount of scientific publications on DSC is growing further larger since and the range of new or renewed more fundamental topics, like solid-state p-conductors and cobalt or organic radical based redox electrolytes, is broadening, as will be explained in the tutorial.

In this sense a growing divergence between market introduction and research could be the consequence. In this tutorial an effort is undertaken to show, that such an unwanted divergence can be prevented by developing suitable reference type cell and module concepts as well as manufacturing routes which can be applied to mesoscopic based solar cells in a broader sense.

As a guideline for developing future mesoscopic cell and module concepts, perovskite solar cells being a prominent example here, our recent work on up-scaling large area glass frit sealed DSC modules [2] for efficiency studies 6.

Another important point addressed in the tutorial is the issue of sustainability both affecting market introduction as well as the direction of fundamental research.

Mathew, A. Yella, P. Gao, R. Humphry-Baker, B. Curchod, N. Ashari-Astani, I. Tavernelli, U.

Rothlisberger, Md. Nazeeruddin and M. Hinsch, W. Veurman, B. Brandt, K. FlarupJensen, S. Seigo Ito Department of Electrical Engineering and Computer Sciences, Graduate School of Engineering, University of Hyogo, Japan Synopsis ; V ery recently, organic-inorganic leads halide based perovskites have emerged as a new class of light absorbers, achieving exceptional progress in solar cell performance.

The structure of perovskite solar cells has been close to that of dye-sensitized solar cells. These types of perovskites have favourable bandgap for photovoltaic applications and large extinction coefficients.

Discovery of its solution processability and stability combined with the earth abundance of the constituent materials has made the lead halide perovskites among the most promising solar cell materials.

The third mehod relies on vacuum evaporation deposition using dual source pods with PbX2 and CH3NH3X, which can produce very thin smooth layers on flat substrates.

These perovskite solar cells have typically employed a wide variety of organic hole conductors. In fact, the current commercial price of high purity spiro-OMeTAD is over ten times that of gold and platinum.

While increased demand lowers this cost in some extent, it is still likely to remain expensive due to its high purity needed for photovoltaic applications.

On the other hand, inorganic copperbased p-type semiconductors, such as CuSCN and CuI, are highly promising as hole conductors, because of their solution processablilty, wide band gap with high conductivity, and lower cost.

In this tutorial, the history, the devise principal, the variation of devise structure and the fabrication methods will be presented for the beginners of prerovskite solar cells.

Topic E ; Photovoltaic Systems Terrestrial Photovoltaic PV power generation is one of the widespread countermeasures to solve environmental and energy problems and is recently becoming the mainstream of energy economy.

Many countries maintain high rates of installed PV 34 Tutorials capacity, which seems to be the trend for the foreseeable future.

With this background, the technologies of efficient PV evaluation grow rapidly in importance.

Furthermore, the decline in gird power quality caused by mass PV introduction is a growing issue in our society.

In this tutorial, we focus on the above topics and explain their current status and future perspective. Joshua S.

Stein, Sandia National Laboratories, Albuquerque, NM USA Synopsis ; Photovoltaic systems are intermittent generation resources and their performance depends on the PV technology and local irradiance, weather, and environmental conditions.

This tutorial will provide a technical overview of how PV technologies are characterized and how energy produced from PV systems is predicted.

This will be done by covering a series of PV performance modeling steps including: irradiance translation, shading, surface reflection, spectral mismatch, IV curve models, array mismatch, inverter performance, and other performance factors.

Participants will be introduced to open source tools that will allow them create detailed, physically-based PV performance models.

If time allows, we will also examine power output characteristics from operating PV systems including: variability, ramp rates, and power quality and discuss how these features influence the integration of PV systems into the electrical grid.

Whatever the device we think to use, it has 35 Tutorials 36 a certain form, that will influence the way we will design it, or, at the end of the process, the shape of our living environment.

Thanks to their features, photovoltaic system offer the designer the possibility of envisioning the use of photovoltaic at the architectural scale building integrated photovoltaic , as well as at the landscape scale.

Different technological and design issues are related to these uses of photovoltaic. In the first case, photovoltaic components are used as parts of the building envelopes, and this implies a relevant importance in developing special BIPV technological elements, which could ensure the desired building performances; or in finding appropriate solutions in order to use standard components on the envelope, in an innovative way.

This topic has been largely investigated in the past years, and the tutorial will give an overview on the general topic of the building integration of photovoltaic, and on the design fundamentals.

In the second case, photovoltaic modules are arranged in the form of solar arrays, without exploiting any other function than generating energy.

They can be understood as a tangible image of an increasing need of energy from renewables to significantly reduce the pollution caused by traditional energy generation systems, but anyway they generate a diffuse concern about the land use and transformation that they cause.

PV and crops are kinds of opposing needs that should share the same limited resource: the land. Because of this reason in many countries local authorities prohibited the installation of PV in agricultural areas; and due to this barrier, in recent years companies working in the PV development have been experimenting with solutions for producing energy and food in the same land area.

Such experiences will be presented and the issue of PV power generation will be addressed from the landscape design point of view PV landscapes.

JR Haruka Airport Express 75min. Limousine bus approx. Subway Karasuma Line Kitaoji St. Imadegawa St.

Horikawa St. Senbon St. Nijo Nijo-jo Castle Nijo Sta. Oike St. Nijojomae Sta. Hankyu Line 27 18 9 30 15 Omiya Sta.

Shijo Sta. Kujo St. Kyoto Sta. Tanbaguchi Sta. Omiya St. Gojo St. Kokusai Kaikan Sta. Kitayama Sta.

Kyoto International Matsugasaki Sta. Kuramaguchi Sta. Demachiyanagi Sta. Imadegawa Sta. Shirakawa St. Higashioji St. City Hall Karasuma Sta.

Nanzenji Temple Kyoto Shiyakusho-mae Sta. Keage Sta. Sanjo Keihan Sta. Keihan Line Shijo Sta. Heian Jingu 19 9 Kawabata St.

Kawaramachi St. Marutamachi Sta. Gion shijo Sta. Kodaiji Temple Gojo Sta. Honganji Kiyomizu Gojo Sta.

Sanyo Electric Co. Toppan Printing Co. Jinko Solar Co. Toray Engineering Co. Toray Industries, Inc. UL Japan, Inc. Stanbery Heliovolt Vice-Chair: A.

Terakawa Panasonic R. Raffaelle Rochester Inst. Wada Ryukoku Univ. Vice-Chair: T. Okamoto Univ. Usami Tohoku Univ.

Ueda Tokyo Univ. Takakura Ritsumeikan Univ. Vice-Chair: M. Nonomura Gifu Univ. Vice-Chairs: S.

Wakao Waseda Univ. Tanaka Panasonic Vice-Chair: Y. Ohshita Toyota Tech Inst. Yamaguchi Toyota Tech Inst. Raffaelle Rochester Institute of Technology J.

Okada Univ. Tokyo Area Co-chair: K. Terakawa Panasonic Area Co-chair: T. Smets Univ. Delft Area Co-chair: C. Dimmler Manz Co. Ogura Meiji Univ.

Takamoto Sharp Area Co-chair: M. Benner Stanford Univ. Area Co-chair: S. Baumgartner Zurich Univ. Konagai Tokyo Tech Secretary: M.

Green, D. Kim, M. Kondo, K. Kurokawa, C-W. Lan, J. Song, M. Tanaka, Y. Benner, D. Flood, L. Kazmerski, R.

King, R. Raffaelle, B. Stanbery, R. Swanson, R. Walters, D. Wilt, C. Helm, A. Mine, S. Nowak, W. Palz, J. Poortmans, G.

De Santi, W. Sinke, A. Jager-Waldau, E. Konagai Vice-Chair: Y. Kuwano Vice-Chair: M. Hashimoto Special advisor: O.

Ikki Secretary: A. Yamada Advisor: Y. Hamakawa Advisor: M. Umeno Advisor: T. Saito Advisor: K. Takahashi Advisor: H.

Matsunami Members: K. Arafune H. Arakawa K. Araki K. Funakawa K. Kurokawa K. Kushiya H. Enomoto S. Maeshima K. Ogimoto Y. Ohshita Y.

Okada H. Okamoto Y. Tawada O. Tsuji Y. Ueda N. Usami 45 Committees T. Fuyuki L. Han S. Hayase M.

Hiramoto Y. Hishikawa T. Hokiyama M. Imaizumi M. Isomura T. Ito K. Kakimoto H. Katagiri M. Kondo A. Masuda H. Matsumura T. Minemoto T. Motohiro T.

Nakada K. Nakajima Y. Nakano T. Negami S. Niki Y. Nishikitani K. Nishioka S. Nonomura T. Oozeki Y. Sakai H. Segawa M. Tajima H. Takakura T.

Takamoto A. Takano H. Takatsuka Y. Takeuchi M. Tanaka R. Tanaka N. Taneda M. Ushijima T. Wada S. Wakao M. Yamaguchi K. Yamamoto M. Yamatani T.

Yanagisawa S. Yoshikawa K. Konagai Vice-Chair: A. Yamada Secretary: Y. Ueda Secretary: S. Miyajima Members: A. Asano Y.

Ohshita T. Wada A. Masuda T. Takamoto M. Yamatani S. Nonomura N. Usami M. Kondo H. Takakura K. Yamamoto Y. Nishikawa A.

Terakawa T. Tajima M. Yamaguchi S. Niki M. Tanaka T. Fuyuki H. Okamoto S. Wakao T. Minemoto H. Tamai T.

Arafune Hyogo Pref. Araki Daido D. Funakwa Honda Soltec L. Hara Hokkaido Univ. Hiramoto Inst. Kambe AGC T. Katagiri Nagaoka-ct 46 H.

Nakaniwa Dupont Japan Y. Nasuno Sharp T. Negami Panasonic S. Nishioka Miyazaki Univ. Ogimoto Univ. Ohkita Kyoto Univ.

Osaka Riken T. Saitoh Fukushims Univ. Segawa Univ. Kojima TTI K. Komoto Mizuho A. Matsubara Kyocera T. Minemoto Ritsumeikan Univ.

Miyajima Tokyo Tech T. Miyasaka Toin Yokohama Univ. Sugiyama Univ. Tanabe Meidensha T. Usami Nagoya Univ. Lan National Taiwan Univ.

Yagi Saitama Univ. Yamada Tokyo Tech K. Yamamoto Kaneka D. Yang Zhejiang Univ. Committees D. Kim Korea Univ.

Kobayashi Gifu Univ. Yi Sungkyunkwan Univ. Zhao Nankai Univ. Konagai Honorary Chairperson: Y. Hamakawa Honorary Chairperson: C. Chung Honorary Chairperson: S.

Panyakeow Members: A. Aberle P. Sichanugrist C. Tsai Y. Matsumoto B. McNelis M. Murthy H. Ossenbrink W.

Palz Y. Peinuo J. Poortmans S. Ray A. Rohatgi T. Saito A. Sayigh H. Schock W. Shafarman W. Shen Ir.

Ahmad Hadri Haris B. Ahn C. Signorini J. Song R. Swanson M. Tanaka M. Umeno T. Wada W. Wenas J. Werner C.

Wronski M. Yamaguchi M. Yamatani D. Yang J. Zhao J. Luther T. Machida A. Barua T. Fuyuki M. Green P. Helm H. Hwang O. Ikki L. Kazmerski D.

Kim M. Kondo D. Kruangam K. Kurokawa Chung-Wen Lan Z. Liu A. Konagai Advisor: Y. Hamakawa Members: T.

Kondo K. Kushiya S. Nonomura H. Okamoto H. Segawa H. Takakura M. Umeno S. Yamaguchi O. Ikki K. Kurokawa S.

Niki K. Ogimoto T. Saito T. Takamoto Y. Tawada T. Yamada M. Yamaguchi Toyota Tech. Vice-Chairs: R. Walters NRL A. Konagai Tokyo Tech D. Kurokawa Tokyo Tech M.

Carlson BP Solar R. Schwartz Purdue Univ. Flood Vangard C. Wronski Penn State Univ. Helm WIP B. Konagai, Tokyo Tech B.

Stanbery, Heliovolt A. Yamaguchi Annex Award Presentation: S. Katsumi Kushiya Solar Frontier K. Stradins1 , S.

Glunz2 and A. He named those composition regions as the active composition. Professor Katagiri has worked as an engineering educator in his college.

All students in his laboratory are undergraduate. In the educational system of Japan, they are regarded to be the youngest researchers.

Professor Katagiri says that both the development of CZTS solar cells and the education of young students are his lifework.

Seishin Trading Co. The tutorial topics and time schedules are listed below. Please register for the tutorials using the normal conference registration process on this web site.

Topic A ; Crystalline Silicon Solar Cells Crystalline silicon solar cells hold a dominant share of the solar cell market, and this situation is expected to continue at least for a decade.

This tutorial will outline the current standard technologies in mass production flow of crystalline silicon solar cells: from crystallization through sawing and cell processes to module production.

In addition, leading technologies for further improvement in the efficiency and reduction of the production cost will be also reviewed.

Kyotaro Nakamura, Meiji University, Japan 28 Synopsis ; C rystalline silicon solar cell has been playing the central role of PV industry for a long time and the crystalline silicon solar cell technology also will continue to be dominant in solar cell production for some time in the future.

This tutorial will cover all aspects of production in crystalline silicon solar cell from the present and into the future. At first, we will instruct device physics and some basic techniques of crystalline silicon solar cells, for example, Texturization, BSF Back Surface Field and so on.

Then, the fabrication process of conventional crystalline silicon solar cells will be introduced. The fundamental fabrication process flow of conventional solar cell is as follows; 1 Sow damage removal and texturing, 2 Phosphorus diffusion and PSG removal, 3 ARC Anti-Reflection Coating formation, and 4 Metallization.

We will explain these steps with showcasing an example of manufacturing line. On the other hand, there are also a number of advanced technologies which will dominate the next wave of large scale deployment on manufacturing lines and in field installation.

So, we will also show some advanced technologies for high efficiency crystalline silicon solar cell and some important achievements in recent years in this field.

Instructor ; D r. This tutorial will instruct material science and technology of silicon crystals, which will cover crystal growth, wafer characterization, and fundamental science of crystal defects.

As the crystal growth topics, new concept growth methods, i. Secondly, principle and feature, in particular detection error and limit, will be discussed for various characterization techniques, such as microPCD, PL imaging, FTIR, and etch pit observation, for silicon wafers and bulk ingots.

Furthermore, lecture of fundamental science of crystal defects will be presented. This lecture will cover generation and propagation mechanism of dislocations and incorporation mechanism of impurities during the crystal growth process that will be a help to develop the growth technologies of silicon ingots.

Topic B ; Thin Film Silicon Solar Cells In this tutorial, there will be three main topics on Si thin film PV, that is, preparations of amorphous and microcrystalline Si, fundamental physics of thin film silicon solar cells including transparent conducting oxides TCO and future outlook of the type of cells.

Furthermore, fundamental physics and preparation techniques of quantum dot and nanowire solar cells will be described.

This suggests that the performance of solar cells could be improved times if fundamentally different new concepts were used in their design.

In addition, there would be an enormous impact on economics if the new concepts could be implemented in thin-film form, making photovoltaics one of the cheapest energy resource.

Nanostructured photovoltaics, such as quantum dot solar cells, are proposed as a potential candidate to demonstrate high performance, low-cost photovoltaics.

To date, while some characteristic operations, such as an enhanced photocurrent generation due to quantum dots, have been confirmed, the conversion efficiency of quantum dot solar cells has remained less than those of conventional single junction solar cells without quantum dots.

In this tutorial, new physical mechanisms for high conversion efficiency will be presented, including multi-exciton generation impact ionization , intermediate-bands, and hot carrier solar cells.

The tutorial will provide fundamental physics and preparation techniques of quantum dots. The principle in quantum dot solar cell operations will be discussed, along with a survey of quantum dot solar cell technologies.

In addition, current status and prospects of quantum dot solar cells for meeting future global energy demands will be presented.

Makoto Tanaka Core Technologies Development Center Eco Solutions Company Panasonic Corporation, Japan 30 Synopsis ; Improvement of energy conversion efficiency of solar cells is an important issue for resolving energysupply problems in the world.

One of the promising materials for realizing solar cells with higher efficiency and lower cost seems to be Si thin film.

The session C-1 will describe both fundamental properties and the recent progress in the characterization methods of the chalcogenide materials for solar cell application, and discuss the material properties to be improved to enhance device performance further.

The session C-2 will present an overview of the recent progress in the development of the device fabrication technique of compound solar cells, placing special emphasis on the chalcogenide solar cells such as CIGS, CZTS, etc.

Also, non-vacuum process will be presented for future low cost cells. Chalcopyrite solar cell absorber growth techniques and their development will be briefly introduced.

The fundamentals of the growth mechanisms of chalcopyrites will be reviewed and compared to other thin film absorbers including kesterite and perovskite absorbers.

Different characterization methods and fundamental material properties to be monitored will be discussed, e.

A focus will be the structural characterization of thin film growth by X-ray diffraction XRD. The in-site detection of crystal phases during the deposition opens valuable optimization pathways, as the formation, transitions and evolutions of different phases can be monitored in real-time.

Different technological approaches concerning the implementation of in-site XRD and an overview of results obtained by this powerful 31 Tutorials technique will be presented and discussed.

In this lecture, basic material properties of CIGS and fabrication methods of component layers Mo back contact, CIGS absorber layer, buffer layer and window layers will be reviewed.

Also, operation mechanism of CIGS solar cells will be explained and physics parameters to improve short-circuit current and open-circuit voltage will be revealed.

In addition, recent progresses of CIGS solar cells will be summarized. Finally, potential of other chalcogenide materials without rare metals will be discussed with some experimental data.

Topic D ; Organic, Dye Sensitized and Perovskite Solar Cells Organic solar cells are a promising candidate for the next generation solar cells, which develop novel indoor and outdoor applications.

The tutorial presents the recent progress and future perspectives of dye-sensitized solar cells, and overviewing of the organic-inorganic hybrid solar cells, particularly focusing on one of the fastest growing organic photovoltaic technology based on organometal halide compounds with the perovskite structure.

The market introduction is accompanied by a strong increase in patent applications in the field during the last 4 years which is a good indication that further commercialization activities are undertaken.

Materials and cell concepts have been developed to such extend that an uptake by industrial manufacturers is possible. The critical phase for a broad market acceptance is therefore reached which implies to focus on standardization related research topics like electrolumi- Tutorials nescence mapping and accelerated testing.

In parallel the amount of scientific publications on DSC is growing further larger since and the range of new or renewed more fundamental topics, like solid-state p-conductors and cobalt or organic radical based redox electrolytes, is broadening, as will be explained in the tutorial.

In this sense a growing divergence between market introduction and research could be the consequence. In this tutorial an effort is undertaken to show, that such an unwanted divergence can be prevented by developing suitable reference type cell and module concepts as well as manufacturing routes which can be applied to mesoscopic based solar cells in a broader sense.

As a guideline for developing future mesoscopic cell and module concepts, perovskite solar cells being a prominent example here, our recent work on up-scaling large area glass frit sealed DSC modules [2] for efficiency studies 6.

Another important point addressed in the tutorial is the issue of sustainability both affecting market introduction as well as the direction of fundamental research.

Mathew, A. Yella, P. Gao, R. Humphry-Baker, B. Curchod, N. Ashari-Astani, I. Tavernelli, U. Rothlisberger, Md. Nazeeruddin and M. Hinsch, W.

Veurman, B. Brandt, K. FlarupJensen, S. Seigo Ito Department of Electrical Engineering and Computer Sciences, Graduate School of Engineering, University of Hyogo, Japan Synopsis ; V ery recently, organic-inorganic leads halide based perovskites have emerged as a new class of light absorbers, achieving exceptional progress in solar cell performance.

The structure of perovskite solar cells has been close to that of dye-sensitized solar cells. These types of perovskites have favourable bandgap for photovoltaic applications and large extinction coefficients.

Discovery of its solution processability and stability combined with the earth abundance of the constituent materials has made the lead halide perovskites among the most promising solar cell materials.

The third mehod relies on vacuum evaporation deposition using dual source pods with PbX2 and CH3NH3X, which can produce very thin smooth layers on flat substrates.

These perovskite solar cells have typically employed a wide variety of organic hole conductors. In fact, the current commercial price of high purity spiro-OMeTAD is over ten times that of gold and platinum.

While increased demand lowers this cost in some extent, it is still likely to remain expensive due to its high purity needed for photovoltaic applications.

On the other hand, inorganic copperbased p-type semiconductors, such as CuSCN and CuI, are highly promising as hole conductors, because of their solution processablilty, wide band gap with high conductivity, and lower cost.

In this tutorial, the history, the devise principal, the variation of devise structure and the fabrication methods will be presented for the beginners of prerovskite solar cells.

Topic E ; Photovoltaic Systems Terrestrial Photovoltaic PV power generation is one of the widespread countermeasures to solve environmental and energy problems and is recently becoming the mainstream of energy economy.

Many countries maintain high rates of installed PV 34 Tutorials capacity, which seems to be the trend for the foreseeable future.

With this background, the technologies of efficient PV evaluation grow rapidly in importance.

Furthermore, the decline in gird power quality caused by mass PV introduction is a growing issue in our society. In this tutorial, we focus on the above topics and explain their current status and future perspective.

Joshua S. Stein, Sandia National Laboratories, Albuquerque, NM USA Synopsis ; Photovoltaic systems are intermittent generation resources and their performance depends on the PV technology and local irradiance, weather, and environmental conditions.

This tutorial will provide a technical overview of how PV technologies are characterized and how energy produced from PV systems is predicted.

This will be done by covering a series of PV performance modeling steps including: irradiance translation, shading, surface reflection, spectral mismatch, IV curve models, array mismatch, inverter performance, and other performance factors.

Participants will be introduced to open source tools that will allow them create detailed, physically-based PV performance models. If time allows, we will also examine power output characteristics from operating PV systems including: variability, ramp rates, and power quality and discuss how these features influence the integration of PV systems into the electrical grid.

Whatever the device we think to use, it has 35 Tutorials 36 a certain form, that will influence the way we will design it, or, at the end of the process, the shape of our living environment.

Thanks to their features, photovoltaic system offer the designer the possibility of envisioning the use of photovoltaic at the architectural scale building integrated photovoltaic , as well as at the landscape scale.

Different technological and design issues are related to these uses of photovoltaic. In the first case, photovoltaic components are used as parts of the building envelopes, and this implies a relevant importance in developing special BIPV technological elements, which could ensure the desired building performances; or in finding appropriate solutions in order to use standard components on the envelope, in an innovative way.

This topic has been largely investigated in the past years, and the tutorial will give an overview on the general topic of the building integration of photovoltaic, and on the design fundamentals.

In the second case, photovoltaic modules are arranged in the form of solar arrays, without exploiting any other function than generating energy.

They can be understood as a tangible image of an increasing need of energy from renewables to significantly reduce the pollution caused by traditional energy generation systems, but anyway they generate a diffuse concern about the land use and transformation that they cause.

PV and crops are kinds of opposing needs that should share the same limited resource: the land. Because of this reason in many countries local authorities prohibited the installation of PV in agricultural areas; and due to this barrier, in recent years companies working in the PV development have been experimenting with solutions for producing energy and food in the same land area.

Such experiences will be presented and the issue of PV power generation will be addressed from the landscape design point of view PV landscapes.

JR Haruka Airport Express 75min. Limousine bus approx. Subway Karasuma Line Kitaoji St. Imadegawa St. Horikawa St. Senbon St.

Nijo Nijo-jo Castle Nijo Sta. Oike St. Nijojomae Sta. Hankyu Line 27 18 9 30 15 Omiya Sta. Shijo Sta. Kujo St.

Kyoto Sta. Tanbaguchi Sta. Omiya St. Gojo St. Kokusai Kaikan Sta. Kitayama Sta. Kyoto International Matsugasaki Sta.

Kuramaguchi Sta. Demachiyanagi Sta. Imadegawa Sta. Shirakawa St. Higashioji St. City Hall Karasuma Sta.

Nanzenji Temple Kyoto Shiyakusho-mae Sta. Keage Sta. Sanjo Keihan Sta. Keihan Line Shijo Sta. Heian Jingu 19 9 Kawabata St.

Kawaramachi St. Marutamachi Sta. Gion shijo Sta. Kodaiji Temple Gojo Sta. Honganji Kiyomizu Gojo Sta. Sanyo Electric Co. Toppan Printing Co.

Jinko Solar Co. Toray Engineering Co. Toray Industries, Inc. UL Japan, Inc. Stanbery Heliovolt Vice-Chair: A.

Terakawa Panasonic R. Raffaelle Rochester Inst. Wada Ryukoku Univ. Vice-Chair: T. Okamoto Univ. Usami Tohoku Univ.

Ueda Tokyo Univ. Takakura Ritsumeikan Univ. Vice-Chair: M. Nonomura Gifu Univ. Vice-Chairs: S. Wakao Waseda Univ.

Tanaka Panasonic Vice-Chair: Y. Ohshita Toyota Tech Inst. Yamaguchi Toyota Tech Inst. Raffaelle Rochester Institute of Technology J.

Okada Univ. Tokyo Area Co-chair: K. Terakawa Panasonic Area Co-chair: T. Smets Univ. Delft Area Co-chair: C.

Dimmler Manz Co. Ogura Meiji Univ. Takamoto Sharp Area Co-chair: M. Benner Stanford Univ. Area Co-chair: S. Baumgartner Zurich Univ. Konagai Tokyo Tech Secretary: M.

Green, D. Kim, M. Kondo, K. Kurokawa, C-W. Lan, J. Song, M. Tanaka, Y. Benner, D. Flood, L. Kazmerski, R. King, R. Raffaelle, B.

Stanbery, R. Swanson, R. Walters, D. Wilt, C. Helm, A. Mine, S. Nowak, W. Palz, J. Poortmans, G. De Santi, W. Sinke, A. Jager-Waldau, E. Konagai Vice-Chair: Y.

Kuwano Vice-Chair: M. Hashimoto Special advisor: O. Ikki Secretary: A. Yamada Advisor: Y. Hamakawa Advisor: M. Umeno Advisor: T. Saito Advisor: K.

Takahashi Advisor: H. Matsunami Members: K. Arafune H. Arakawa K. Araki K. Funakawa K. Kurokawa K. Kushiya H. Enomoto S. Maeshima K.

Ogimoto Y. Ohshita Y. Okada H. Okamoto Y. Tawada O. Tsuji Y. Ueda N. Usami 45 Committees T. Fuyuki L. Han S. Hayase M. Hiramoto Y. Hishikawa T.

Hokiyama M. Imaizumi M. Isomura T. Ito K. Kakimoto H. Katagiri M. Kondo A. Masuda H. Matsumura T. Minemoto T. Motohiro T.

Nakada K. Nakajima Y. Nakano T. Negami S. Niki Y. Nishikitani K. Nishioka S. Nonomura T. Oozeki Y. Sakai H.

Segawa M. Tajima H. Takakura T. Takamoto A. Takano H. Takatsuka Y. Takeuchi M. Tanaka R. Tanaka N.

Taneda M. Ushijima T. Wada S. Wakao M. Yamaguchi K. Yamamoto M. Yamatani T. Yanagisawa S. Yoshikawa K.

Konagai Vice-Chair: A. Yamada Secretary: Y. Ueda Secretary: S. Miyajima Members: A. Asano Y. Ohshita T. Wada A. Masuda T.

Takamoto M. Yamatani S. Nonomura N. Usami M. Kondo H. Takakura K. Yamamoto Y. Nishikawa A. Terakawa T. Tajima M. Yamaguchi S. Niki M.

Tanaka T. Fuyuki H. Okamoto S. Wakao T. Minemoto H. Tamai T. Arafune Hyogo Pref. Araki Daido D. Funakwa Honda Soltec L. Hara Hokkaido Univ.

Hiramoto Inst. Kambe AGC T. Katagiri Nagaoka-ct 46 H. Nakaniwa Dupont Japan Y. Nasuno Sharp T. Negami Panasonic S. Nishioka Miyazaki Univ.

Ogimoto Univ. Ohkita Kyoto Univ. Osaka Riken T. Saitoh Fukushims Univ. Segawa Univ. Kojima TTI K. Komoto Mizuho A. Matsubara Kyocera T.

Minemoto Ritsumeikan Univ. Miyajima Tokyo Tech T. Miyasaka Toin Yokohama Univ. Sugiyama Univ. Tanabe Meidensha T. Usami Nagoya Univ.

Lan National Taiwan Univ. Yagi Saitama Univ. Yamada Tokyo Tech K. Yamamoto Kaneka D. Yang Zhejiang Univ.

Committees D. Kim Korea Univ. Kobayashi Gifu Univ. Yi Sungkyunkwan Univ. Zhao Nankai Univ. Konagai Honorary Chairperson: Y.

Hamakawa Honorary Chairperson: C. Chung Honorary Chairperson: S. Panyakeow Members: A. Aberle P. Sichanugrist C. Tsai Y. Matsumoto B. McNelis M.

Murthy H. Ossenbrink W. Palz Y. Peinuo J. Poortmans S. Ray A. Rohatgi T. Saito A. Sayigh H. Schock W.

Shafarman W. Shen Ir. Ahmad Hadri Haris B. Ahn C. Signorini J. Song R. Swanson M. Tanaka M. Umeno T. Wada W.

Wenas J. Werner C. Wronski M. Yamaguchi M. Yamatani D. Yang J. Zhao J. Luther T. Machida A. Barua T.

Fuyuki M. Green P. Helm H. Hwang O. Ikki L. Kazmerski D. Kim M. Kondo D. Kruangam K. Kurokawa Chung-Wen Lan Z.

Liu A. Konagai Advisor: Y. Hamakawa Members: T. Kondo K. Kushiya S. Nonomura H. Okamoto H. Segawa H. Takakura M. Umeno S.

Yamaguchi O. Ikki K. Kurokawa S. Niki K. Ogimoto T. Saito T. Takamoto Y. Tawada T. Yamada M. Yamaguchi Toyota Tech.

Vice-Chairs: R. Walters NRL A. Konagai Tokyo Tech D. Kurokawa Tokyo Tech M. Carlson BP Solar R.

Schwartz Purdue Univ. Flood Vangard C. Wronski Penn State Univ. Helm WIP B. Konagai, Tokyo Tech B. Stanbery, Heliovolt A.

Yamaguchi Annex Award Presentation: S. Katsumi Kushiya Solar Frontier K. Stradins1 , S. Glunz2 and A. Ogusu1 , M. Konagai1,2 and S. Martin de Nicolas, S.

De Wolf, B. Demaurex, J. Holm, P. Paviet-Salomon, J. Seif, A. Tomasi and C. Ballif 3MoO. Reinhard, M. Werner, B.

Bissig, F. Pianezzi, C. Sutter-Fella, H. Hagendorfer, S. Nishiwaki, Y. Romanyuk, S. Buecheler, and A. Ishizuka1 , A.

Yamada1 , P. Fons2 , H. Shibata1 and S. Maeda, A. Kawabata and T. Nishimura1 , Y. Hirai1 , Y. Kurokawa1 and A. Khatri, I. Matsuyama, H.

Yamaguchi and T. Hara1 , T. Maekawa2 , S. Minoura1 , Y. Kamikawa3 , H. Shibata3 , S. Niki3 and H. Hinrichs, V. Handke, L.

Chikhaoui and M. LuxSteiner B. Stegemann1 , M. Schultz1 , K. Stelmaszczyk1,2 , M. Weizman1 , C. Wolf2 , C. Kaufmann2 , B. Rau2 , R. Schlatmann1,2 , V.

Quaschning1 and F. Niki1 , S. Ishizuka1 , Y. Kamikawa1 , J. Nishinaga1 , H. Tampo1 , K. Matsubara1 , H.

Shibata1 , A. Yamada1 , K. Hara2 , A. Masuda2 , N. Terada3 , T. Sakurai4 and K. Ramanathan, L. Mansfield, R.

Garris, S. Glynn, B. Egaas and M. Shrestha, G. Conibeer, S. Huang, S. Chung, N. Gupta, Y. Liao, Y. Feng, H. Xia, S.

Smyth, X. R Dimmock1,2 , M. Kauer1 , K. Smith1 , P. Stavrinou2 and N. Yao and J. Isabella, A. Ingenito, F. Si, R. Vismara and M. Kanematsu1,2 , S.

Yata1 , A.

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