Nanostructured Materials for Type III Photovoltaics
Nonfiction, Science & Nature, Science, Chemistry, Technical & Industrial, Physics, Energy, Technology
| Author: | David Binks, Natalie Banerji, Natalie Stingelin, Serdar Sariciftci, Garry Rumbles, Iain McCulloch, Neil Robertson, Neerish Revaprasadu, Russell Binions, David Lewis, Vimal Kumar Jain, Karthik Ramasamy, Xiaowei Zhan, Peter Skabara, Henry Snaith, Paul O'Brien | ISBN: | 9781788012508 |
| Publisher: | Royal Society of Chemistry | Publication: | November 8, 2017 |
| Imprint: | Royal Society of Chemistry | Language: | English |
| Author: | David Binks, Natalie Banerji, Natalie Stingelin, Serdar Sariciftci, Garry Rumbles, Iain McCulloch, Neil Robertson, Neerish Revaprasadu, Russell Binions, David Lewis, Vimal Kumar Jain, Karthik Ramasamy, Xiaowei Zhan, Peter Skabara, Henry Snaith, Paul O'Brien |
| ISBN: | 9781788012508 |
| Publisher: | Royal Society of Chemistry |
| Publication: | November 8, 2017 |
| Imprint: | Royal Society of Chemistry |
| Language: | English |
Materials for type III solar cells have branched into a series of generic groups. These include organic ‘small molecule’ and polymer conjugated structures, fullerenes, quantum dots, copper indium gallium selenide nanocrystal films, dyes/TiO2 for Grätzel cells, hybrid organic/inorganic composites and perovskites. Whilst the power conversion efficiencies of organic solar cells are modest compared to other type III photovoltaic materials, plastic semiconductors provide a cheap route to manufacture through solution processing and offer flexible devices. However, other types of materials are proving to be compatible with this type of processing whilst providing higher device efficiencies. As a result, the field is experiencing healthy competition between technologies that is pushing progress at a fast rate. In particular, perovskite solar cells have emerged very recently as a highly disruptive technology with power conversion efficiencies now over 20%. Perovskite cells, however, still have to address stability and environmental issues. With such a diverse range of materials, it is timely to capture the different technologies into a single volume of work. This book will give a collective insight into the different roles that nanostructured materials play in type III solar cells. This will be an essential text for those working with any of the devices highlighted above, providing a fundamental understanding and appreciation of the potential and challenges associated with each of these technologies.
Materials for type III solar cells have branched into a series of generic groups. These include organic ‘small molecule’ and polymer conjugated structures, fullerenes, quantum dots, copper indium gallium selenide nanocrystal films, dyes/TiO2 for Grätzel cells, hybrid organic/inorganic composites and perovskites. Whilst the power conversion efficiencies of organic solar cells are modest compared to other type III photovoltaic materials, plastic semiconductors provide a cheap route to manufacture through solution processing and offer flexible devices. However, other types of materials are proving to be compatible with this type of processing whilst providing higher device efficiencies. As a result, the field is experiencing healthy competition between technologies that is pushing progress at a fast rate. In particular, perovskite solar cells have emerged very recently as a highly disruptive technology with power conversion efficiencies now over 20%. Perovskite cells, however, still have to address stability and environmental issues. With such a diverse range of materials, it is timely to capture the different technologies into a single volume of work. This book will give a collective insight into the different roles that nanostructured materials play in type III solar cells. This will be an essential text for those working with any of the devices highlighted above, providing a fundamental understanding and appreciation of the potential and challenges associated with each of these technologies.
