Programm Photovoltaik Ausgabe 2008 ... - Bundesamt für Energie BFE

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FULLSPECTRUM Département fédéral de l’environnement, des transports, de l’énergie et de la communication DETEC Office fédéral de l’énergie OFEN A NEW PV WAVE MAKING MORE EFFICIENT USE OF THE SOLAR SPECTRUM Annual Report 2007 Author and Co-Authors Dr. Toby Meyer & Andreas Meyer Institution / Company Solaronix SA Address Ouriette 129 CH-1170 Aubonne Telephone, E-mail, Homepage +41 (0) 21 821 22 80, toby@solaronix.com, www.solaronix.com Project- / Contract Number SES6-CT-2003-502620 / SER N° 03.0111-2 Duration of the Project (from – to) 1.11.2003 – 31.10.<strong>2008</strong> Date 05.02.<strong>2008</strong> ABSTRACT FULLSPECTRUM is an EU integrated project whose primary objective is to make use of the FULL solar SPECTRUM to produce electricity. The necessity for this research is easily understood, for example, from the fact that present commercial solar cells used for terrestrial applications are based on single gap semiconductor solar cells. These cells can by no means make use of the energy of below bandgap energy photons, since these simply cannot be absorbed by the material. The achievement of this general objective is pursued through five strategies: a) the development of high efficiency multijunction solar cells based on III-V compounds, b) the development of thermophotovoltaic converters, c) the research on intermediate band solar cells, d) the search of molecules and dyes capable of undergoing two photon processes and e) the development of manufacturing techniques suitable to industrialize the most promising concepts. Seite 123 von 288
Seite 124 von 288 Project Goals The aim of FULLSPECTRUM is the development of photovoltaic (PV) concepts capable of extracting the most of every single photon available [1]. At this respect, each of the five activities envisaged in this project to achieve this general goal confront its own challenges. The multijunction activity pursues to develop solar cells that approach 40 % efficiency as much as possible. For that, it faces the challenge of finding materials with a good compromise between lattice matching and bandgap energy. The thermophotovoltaic activity bases part of its success in finding suitable emitters that can operate at high temperatures and/or adapt their emission spectra to the gap of the cells. The other part relies in the successful recycling of photons so that those that cannot be used effectively by the solar cells can return to the emitter assisting in keeping it hot. The intermediate band solar cell approach defy the challenge of proving its principles of operation to an extent in which these have not represent only marginal effects in the performance of the cells. The molecular based concept activity devoted to search of new molecules encounters the challenge of identifying molecules capable of undergoing two photon processes, that is, molecules that can absorb two low energy photons to produced a high energy excited state or, for example, dyes that can absorb one high energy photon and re-emit its energy in the form of two photons of lower energy. An other aim is investigating the "flat-plate concentrator" (FPC) concept, which is based on thin polymers sheets colored with special dyes capable of absorbing high-energy photons and re-emit them as low energy photons that ideally match the gap of the solar cells. This emitted light is trapped within the concentrator usually by internal reflection and, if the losses within the concentrator are small, can only escape by being absorbed by the cells put on the edges of the concentrator plate. Among all the above concepts, the multijunction approach appears to be the most readily available for commercialization. For that, the manufacturing techniques and pre-normative research activity is devoted specifically to speed up its path to market is developing trackers, optics and manufacturing techniques that can integrate these cells in commercial concentrator systems. Short description of the project The multijunction solar cell approach pursues the better use of the solar spectrum by using a stack of single gap solar cells to be incorporated in a concentrator system in order to make it cost effective (Fig. 1). Within this approach, the project, at its start, aimed to cells with an efficiency of 35 %. This result has already been achieved by FhG-ISE in the second year of the Project and the Consortium aims now to achieve efficiencies as close as possible to 40%. Fig. 1. Example of a structure of a monolithic triple-junction solar cell made of Ga0.35In0.65P -, Ga0.83In0.17As - and Ge-junctions interconnected by internal tunnel diodes. FULLSPECTRUM, T. Meyer, Solaronix 2/8
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Forschung, April 2008 Programm Phot
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Programm Photovoltaik Ausgabe 2008
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T. Meyer ORGAPVNET: Coordination Ac
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PROGRAMM PHOTOVOLTAIK Eidgenössisc
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1. Programmschwerpunkte und anvisie
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Ein neues KTI-Projekt Flexible Phot
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In einem neuen, durch den Axpo Natu
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Performanz und Energieproduktion vo
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ERGÄNZENDE PROJEKTE UND STUDIEN En
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in diesem Projekt für die Koordina
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5. Pilot- und Demonstrationsprojekt
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Produktionskapazität von insgesamt
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[26] H. Häberlin, L. Borgna, D. Gf
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[89] Konzept der Energieforschung d
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Solarzellen C. Ballif, J. Bailat, F
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Département fédéral de l’envir
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3/9 Fig. 1: Refractive index n and
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5/9 V oc [mV] 940 920 900 880 860 8
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7/9 Fig. 5: Top) SEM micrographs of
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9/9 Acknowledgements The co-workers
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Seite 40 von 288 Introduction and f
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Seite 42 von 288 Introduction / Pro
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Seite 44 von 288 Results The amorph
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Seite 46 von 288 Collaborations IMT
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Seite 48 von 288 Introduction / Pro
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Seite 50 von 288 High efficiency so
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Seite 52 von 288 Towards low costs
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Eidgenössisches Departement für U
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3/6 The Athlet consortium comprises
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5/6 Large area cluster deposition s
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SIWIS Département fédéral de l
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3/6 Results Defects characterizatio
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5/6 The test methodology was optimi
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Seite 70 von 288 Summary of Applied
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Page 89 and 90: Seite 86 von 288 Intensity / arb. u
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Page 111 and 112: Introduction The work to be reporte
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Page 119 and 120: Figure 2: Upper panel: isodensity p
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Page 135 and 136: Project Goals The goal is the estab
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The following list shows the measur
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data sets. The indoor data sets con
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The blind round-robin proved that o
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Einleitung / Projektziele Herstelle
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Abb. 1, und deren Mittelwert für d
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Aus Gleichung (1) ergeben sich der
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Abb. 7: Abhängigkeit des Wirkungsg
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Der Rechengang zu Abb.8 läuft wie
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Wie erwartet ist der Jahresmittelwe
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Projektziele für 2007 � Ununterb
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Generator-Korrekturfaktor k G in %
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WR-Defekte pro WR-Betriebsjahr 0.8
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Nationale / internationale Zusammen
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Einleitung / Projektziele Dezentral
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BON: Betrieb ohne Netz oder USV-Bet
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An einem Workshop mit EWs in Kalifo
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Challenges The liberalisation of th
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W 900 800 700 600 500 400 300 200 1
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PV-BUK Eidgenössisches Departement
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3/6 häufigsten traten jedoch Gesam
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5/6 Die Gespräche mit verschiedene
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3/10 Tab. 1: Overview of the types
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5/10 Tab. 2: Key parameters of the
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7/10 horizontal surface (kWh/m 2 )
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9/10 6. Conclusion and Outlook The
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3/9 Fig.2: Photograph of SiO2:CdS s
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5/9 Fig. 4: Photoluminescence spect
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7/9 In general, the performance of
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9/9 Conclusions � A large Stokes
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Einleitung / Projektziele Solaranla
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Internationale Koordination P. Hüs
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Kurzbeschrieb des Projekts Task 1 u
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Trends Report Basierend auf den Dat
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Einleitung / Projektziele Die Ziele
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Case Studies Als Ergänzung zu den
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3/10 Ziele 2007 Die Ziele der REPIC
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5/10 Die restlichen 13 Projektantr
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7/10 Stand der technischen REPIC Pr
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9/10 Förderung der Solarenergie f
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3/6 Les avantages pour le consommat
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5/6 SOUS-TÂCHE 4 « Information et
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3/3 Turbidity climatology Turbidity
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Einleitung / Projektziele Normenarb
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IEC 62548 Installation and Safety R
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Referenzen Eine vollständige Liste
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Introduction and Goals PV ERA NET i
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WP2: Strategy Issues: The main acti
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A dedicated transnational call “P
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Databases have been developed for o
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Programm Photovoltaik Ausgabe 2008 ... - Bundesamt für Energie BFE

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