Leistungen
This covers the quality management related to both the project implementation and the technological developments. (Task 6.6)
Risk assessment and mitigation strategyReport describing the risk assessment of the PK technology, including the methodologies and final results, as well as the refined risk mitigation strategy. (Task 3.3)
Second Industry WorkshopSecond Industry Workshop for presenting the CHEOPS technologies to the Industrial Advisory Board members (Task 5.3)
Semi-transparent (> 40% transparency) mini-module with 10% stabilised aperture area efficiency on 20cm x 30cmThe deliverable comprises the mini-module with efficiency determined following the established protocol, as well as a brief report documenting the production of the mini-module and the measurements (Task 2.4).
Roadmap for future developments of the PK technologyReport describing the refined future development roadmap, including a description of the process of elaboration of the roadmap. (Task 3.5)
Socio-economic analysis of CHEOPS technologies and benchmarkingReport describing the socio economic analysis, including the methodologies, data bases and assumptions used as well as the results for both the single junction as well as the PK/c-Si SHJ tandem devices. (Task 3.4)
Report on best encapsulation processes compatible with perovskite PV technologyThe report will document the activities and results of Task 2.2 and will present a recommendation for current best process for encapsulation process (Task 2.2).
Best practice recommendations and contribution to standardsThis deliverable comprises the actual delivery of recommendations to the relevant stakeholders and contributions to standardisation committees. In addition, the deliverable report will summarise the approach taken. (Task 5.5)
Life Cycle Analysis of CHEOPS technologies and benchmarking: ScreeningReport describing the resource efficiency analysis, including the methodology, data basis and assumptions used as well as the results for both the single junction as well as the PK/c-Si SHJ tandem devices. (Task 3.2)
Report on process flow for small scale single junction device productionThe report provides a summary and synthesis of the activities and results of Tasks 1.1-1.4 in terms of the currently best process flow (Tasks 1.1 - 1.4)
Data Management Plan (DMP)This covers the use and maintenance of all data generated in this project and is binding for all partners. (Task 6.3)
Report on monitoring competing research developmentsThe deliverable report describes the approach taken for the monitoring as well as the results and conclusions drawn for own future activities (Task 5.4)
First Industry WorkshopFirst Industry Workshop for presenting the CHEOPS technologies to the Industrial Advisory Board members. (Task 5.3)
Report on measurement and stability testing protocolsThe report will document the activities carried out in Task 2.1 and the results obtained and will present a recommendation for best practice in terms of measurement and stability testing protocols (Task 2.1).
Life Cycle Analysis of CHEOPS technologies and benchmarking: Final assessmentReport describing the resource efficiency analysis, including the methodology, data basis and assumptions used as well as the results for both the single junction as well as the PK/c-Si SHJ tandem devices. (Task 3.2)
Report on complete optimised process flow for high stable efficiency single junction module production implemented at pilot lineThe report provides a summary and synthesis of the activities and results of Tasks 2.1-2.4 in terms of the currently best process flow (Tasks 2.1 - 2.4).
In addition to the module with stable efficiency confirmed using measurement protocols developed in T2.1.3, the deliverable also comprises a brief report documenting the production process and the measurements carried out. (Tasks 1.1 - 1.4)
15x15 cm2 device with stabilised aperture area efficiency of 14% and report on required process flowThe deliverable comprises the device with efficiency confirmed by measurement protocols developed in T2.1.3 as well as a brief report documenting the activities and results of Task 2.3 (Task 2.3).
A 10x10 cm2 module with an initial active area efficiency of 15% (12% stable)In addition to the module with stable efficiency confirmed using measurement protocols developed in T2.1.3, the deliverable also comprises a brief report documenting the production process and the measurements carried out. (Tasks 1.1 - 1.4)
2x2 cm2 PK/silicon tandem solar cell with a Voc >1.84 V, a Jsc >19 mA/cm2 and a FF >83% corresponding to an efficiency >29%The deliverable comprises both the tandem cell as well as an expanded version of the D4.4 report with updates on the activities carried out in Task 4.3 in the final year of the project. (Task 4.3)
Lead free PK lab scale cell with a stable efficiency of 15% on active area of 1cm2The deliverable comprises the lab scale cell with its stable efficiency confirmed by an independent certified laboratory. In addition it comprises a brief report summarising the research and development and the measurements carried out. (Task 1.5)
26% PK/silicon tandem solar cell with 1 cm2 areaThe deliverable comprises both the tandem cell as well as a brief report summarising the activities in Task 43 and documenting the efficiency measurements Task 43
Demonstration of improved processes for charge transport layer and PK film deposition leading to an increased Voc of 5% and an increased FF by 2% absolute with a PK layer homogeneity leading to LBIC map variation smaller than 5% on a 5x5 cm2 surfaceDemonstration of improved processes for charge transport layer and PK film deposition leading to an increased Voc of 5% and an increased FF by 2% absolute with a PK layer homogeneity leading to Laser beam Induced Current (LBIC) map variation, on a 5x5 cm2 surface, smaller than 5%. (Tasks 1.1 & Task 1.2)
Low-temperature PK process with 16% efficiency on lab scaleLow-temperature PK process with 16% efficiency on lab scale measured following the protocol developed in T2.1.3. Report summarising the activities in Task 4.2 during the first year of the project and describing the resulting process. (Task 4.2)
Demonstration of patterning processes allowing to achieve death area width < 500 µmThe patterning process will be demonstrated on devices with an area of 5x5 cm2 and death area width will be determined via SEM or optical microscope. (Task 1.4)
Demonstration of improved front electrode opto-electrical and morphologic properties leading to a 1 mA/cm2 current gainDemonstration of improved front electrode opto-electrical and morphologic properties. The layer properties as defined in Task 1.3 above (total transmittance > 85%, sheet resistance <10 Ω/□ and surface roughness < 30 nm) will be confirmed by standard measurement protocols on samples of 1cm2. The improved front electrode opto-electrical and morphological properties lead to at least a 1mA/cm2 photo-generated current gain for single junction devices. The deliverable also comprises a brief report documenting the research and development carried out in Task 1.3 (Task 1.3)
The deliverable comprises the actual CHEOPS website with target group specific information being available online as well as a brief report summarising the website development and documenting technical specifications required for future further development and expansion of the website. (Task 5.2)
Veröffentlichungen
Autoren:
J. L. Hodgkinson, H. M. Yates, A. Walter, D. Sacchetto, S.-J. Moon, S. Nicolay
Veröffentlicht in:
Journal of Materials Chemistry C, Ausgabe 6/8, 2018, Seite(n) 1988-1995, ISSN 2050-7534
Herausgeber:
Royal Society of Chemistry
DOI:
10.1039/C8TC00110C
Autoren:
Jérémie Werner, Loris Barraud, Arnaud Walter, Matthias Bräuninger, Florent Sahli, Davide Sacchetto, Nicolas Tétreault, Bertrand Paviet-Salomon, Soo-Jin Moon, Christophe Allebé, Matthieu Despeisse, Sylvain Nicolay, Stefaan De Wolf, Bjoern Niesen, Christophe Ballif
Veröffentlicht in:
ACS Energy Letters, Ausgabe 1/2, 2016, Seite(n) 474-480, ISSN 2380-8195
Herausgeber:
ACS Publications
DOI:
10.1021/acsenergylett.6b00254
Autoren:
Jérémie Werner, Arnaud Walter, Esteban Rucavado, Soo-Jin Moon, Davide Sacchetto, Michael Rienaecker, Robby Peibst, Rolf Brendel, Xavier Niquille, Stefaan De Wolf, Philipp Löper, Monica Morales-Masis, Sylvain Nicolay, Bjoern Niesen, Christophe Ballif
Veröffentlicht in:
Applied Physics Letters, Ausgabe 109/23, 2016, Seite(n) 233902, ISSN 0003-6951
Herausgeber:
American Institute of Physics
DOI:
10.1063/1.4971361
Autoren:
Fabio Matteocci, Lucio Cinà, Enrico Lamanna, Stefania Cacovich, Giorgio Divitini, Paul A. Midgley, Caterina Ducati, Aldo Di Carlo
Veröffentlicht in:
Nano Energy, Ausgabe 30, 2016, Seite(n) 162-172, ISSN 2211-2855
Herausgeber:
Elsevier BV
DOI:
10.1016/j.nanoen.2016.09.041
Autoren:
Alessandro Lorenzo Palma, Fabio Matteocci, Antonio Agresti, Sara Pescetelli, Emanuele Calabro, Luigi Vesce, Silke Christiansen, Michael Schmidt, Aldo Di Carlo
Veröffentlicht in:
IEEE Journal of Photovoltaics, Ausgabe 7/6, 2017, Seite(n) 1674-1680, ISSN 2156-3381
Herausgeber:
IEEE Electron Devices Society
DOI:
10.1109/jphotov.2017.2732223
Autoren:
Melissa M. McCarthy, Arnaud Walter, Soo-Jin Moon, Nakita K. Noel, Shane O’Brien, Martyn E. Pemble, Sylvain Nicolay, Bernard Wenger, Henry J. Snaith, Ian M. Povey
Veröffentlicht in:
MRS Advances, Ausgabe 3/51, 2018, Seite(n) 3075-3084, ISSN 2059-8521
Herausgeber:
Materials Research Society
DOI:
10.1557/adv.2018.515
Autoren:
M. Afzaal, B. Salhi, A. Al-Ahmed, H. M. Yates, A. S. Hakeem
Veröffentlicht in:
Journal of Materials Chemistry C, Ausgabe 5/33, 2017, Seite(n) 8366-8370, ISSN 2050-7534
Herausgeber:
Royal Society of Chemistry
DOI:
10.1039/c7tc02968c
Autoren:
Shreya Basak, Mohammad Afzaal, Heather M. Yates
Veröffentlicht in:
Materials Chemistry and Physics, Ausgabe 223, 2019, Seite(n) 157-163, ISSN 0254-0584
Herausgeber:
Elsevier BV
DOI:
10.1016/j.matchemphys.2018.10.054
Autoren:
Arnaud Walter, Soo-Jin Moon, Brett A. Kamino, Linus Lofgren, Davide Sacchetto, Fabio Matteocci, Babak Taheri, Julien Bailat, Aldo Di Carlo, Christophe Ballif, Sylvain Nicolay
Veröffentlicht in:
IEEE Journal of Photovoltaics, Ausgabe 8/1, 2018, Seite(n) 151-155, ISSN 2156-3381
Herausgeber:
IEEE Electron Devices Society
DOI:
10.1109/jphotov.2017.2765082
Autoren:
Henry J. Snaith, Peter Hacke
Veröffentlicht in:
Nature Energy, Ausgabe 3/6, 2018, Seite(n) 459-465, ISSN 2058-7546
Herausgeber:
Springer Nature Publishing
DOI:
10.1038/s41560-018-0174-4
Autoren:
Henry J. Snaith
Veröffentlicht in:
Nature Materials, Ausgabe 17/5, 2018, Seite(n) 372-376, ISSN 1476-1122
Herausgeber:
Nature Publishing Group
DOI:
10.1038/s41563-018-0071-z
Autoren:
Florent Sahli, Jérémie Werner, Brett A. Kamino, Matthias Bräuninger, Raphaël Monnard, Bertrand Paviet-Salomon, Loris Barraud, Laura Ding, Juan J. Diaz Leon, Davide Sacchetto, Gianluca Cattaneo, Matthieu Despeisse, Mathieu Boccard, Sylvain Nicolay, Quentin Jeangros, Bjoern Niesen, Christophe Ballif
Veröffentlicht in:
Nature Materials, Ausgabe 17/9, 2018, Seite(n) 820-826, ISSN 1476-1122
Herausgeber:
Nature Publishing Group
DOI:
10.1038/s41563-018-0115-4
Autoren:
Mohammad Afzaal, Heather M. Yates
Veröffentlicht in:
Surface and Coatings Technology, Ausgabe 321, 2017, Seite(n) 336-340, ISSN 0257-8972
Herausgeber:
Elsevier BV
DOI:
10.1016/j.surfcoat.2017.05.011
Autoren:
S. Cacovich, L. Ciná, F. Matteocci, G. Divitini, P. A. Midgley, A. Di Carlo, C. Ducati
Veröffentlicht in:
Nanoscale, Ausgabe 9/14, 2017, Seite(n) 4700-4706, ISSN 2040-3364
Herausgeber:
Royal Society of Chemistry
DOI:
10.1039/C7NR00784A
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