Controlling C 60 fullerene nanocolumn morphology for organic photovoltaic applications

Par Conseil national de recherches du Canada

DOI	Trouver le DOI : https://doi.org/10.1109/PVSC.2011.6186060
Auteur	Rechercher : Thomas, Michael¹; Rechercher : Worfolk, Brian J.¹; Rechercher : Rider, David A.¹; Rechercher : Taschuk, Michael T.¹; Rechercher : Buriak, Jillian M.¹; Rechercher : Brett, Michael J.¹
Affiliation	Conseil national de recherches du Canada. Institut national de nanotechnologie
Format	Texte, Article
Conférence	37th IEEE Photovoltaic Specialists Conference, PVSC 2011, June 19-24, 2011, Seattle, WA, USA
Sujet	Bulk heterojunction; Dead-ends; Deposition angle; Exciton dissociation; Free charge carriers; Glancing Angle Deposition; Hetero interfaces; Indium tin oxide coated glass; Motion algorithm; Nano-columns; Nano-structured; Nano-structuring; Nanocolumn; Nanomorphologies; Organic photovoltaic cells; Planar devices; Substrate rotation; Excitons; Heterojunctions; Indium compounds; Morphology; Photoelectrochemical cells; Photovoltaic cells; Substrates; Tin oxides; Photovoltaic effects
Résumé	We investigate nanostructuring approaches in inverted organic photovoltaic cells to increase exciton harvesting. Conventional bulk heterojunctions (BHJs) have disordered morphologies which increase exciton dissociation. However, in BHJs free charge carriers can be trapped in pocket domains and dead ends. Using glancing angle deposition (GLAD) we fabricate vertical nanocolumns to increase heterointerface area while improving charge transport. Nanostructured C 60 columns have been fabricated using GLAD on transparent indium tin oxide coated glass substrates. GLAD can control intercolumn spacing, column shape, film thickness and other properties. When depositing at constant substrate rotation vertical C 60 columns were achieved. Intercolumn spacing was controlled by the deposition angle between substrate and source. To further approach the ideal nanostructure for organic photovoltaic cells (OPVs), the column diameter was controlled through a substrate motion algorithm called phi-sweep. The engineered GLAD nanomorphology yielded a fivefold increase in short-circuit current when compared to planar devices and a two-fold increase in short-circuit current when compared with bulk heterojunctions. © 2011 IEEE.
Date de publication	2011
Dans	37th IEEE Photovoltaic Specialists Conference (PVSC), 2011 : 19 - 24 June 2011, Seattle, Washington ; conference proceedings, 6186060 (2011) : 744–747.
Série	Conference Record of the IEEE Photovoltaic Specialists Conference.
Langue	anglais
Publications évaluées par des pairs	Oui
Numéro NPARC	21271930
Exporter la notice	Exporter en format RIS
Signaler une correction	Signaler une correction (s'ouvre dans un nouvel onglet)
Identificateur de l’enregistrement	3a30dc41-cd78-41d9-992c-e101992f4af4
Enregistrement créé	2014-05-06
Enregistrement modifié	2020-04-21

Date de modification :: 2024-06-30