Surface plasmon increase absorption in polymer photovoltaic cells
- 10 September 2007
- journal article
- research article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 91 (11), 113514
- https://doi.org/10.1063/1.2782910
Abstract
The authors demonstrate the triggering of surface plasmons at the interface of a metalgrating and a photovoltaic bulk heterojunction blend of alternating polyfluorenes and a fullerene derivative. An increased absorption originating from surface plasmon resonances is confirmed by experimental reflection studies and theoretical modeling. Plasmonic resonances are further confirmed to influence the extracted photocurrent from devices. More current is generated at the wavelength position of the plasmon resonance peak. High conductivity polymer electrodes are used to build inverted sandwich structures with top anode and bottom metalgrating, facilitating for triggering and characterization of the surface plasmon effects.This publication has 21 references indexed in Scilit:
- New Architecture for High‐Efficiency Polymer Photovoltaic Cells Using Solution‐Based Titanium Oxide as an Optical SpacerAdvanced Materials, 2006
- Chiral Interactions in Azobenzene Dimers: A Combined Experimental and Theoretical StudyChemistry – A European Journal, 2005
- Enhanced semiconductor optical absorption via surface plasmon excitation in metal nanoparticlesApplied Physics Letters, 2005
- Long-range absorption enhancement in organic tandem thin-film solar cells containing silver nanoclustersJournal of Applied Physics, 2004
- Organic solar cells: An overviewJournal of Materials Research, 2004
- Wafer scale patterning by soft UV-Nanoimprint LithographyMicroelectronic Engineering, 2004
- Diffraction gratings and buried nano-electrodes—architectures for organic solar cellsThin Solid Films, 2004
- High‐Performance Polymer Solar Cells of an Alternating Polyfluorene Copolymer and a Fullerene DerivativeAdvanced Materials, 2003
- The role of surface plasmons in organic light-emitting diodesIEEE Journal of Selected Topics in Quantum Electronics, 2002
- SOFT LITHOGRAPHYAnnual Review of Materials Science, 1998