Low-threshold polymeric distributed feedback lasers with metallic contacts
- 26 April 2004
- journal article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 84 (17) , 3262-3264
- https://doi.org/10.1063/1.1712029
Abstract
Optical losses in waveguides comprising metallic contacts are thought to be a major hurdle to the realization of organic laser diodes. We demonstrate here that careful tuning of the waveguide mode in flexible distributed feedback lasers can allow lasing action to occur in organic thin films in the presence of contacting electrodes with virtually no difference when compared to metal free devices. A metallic electrode is most suited as the bottom contact between the polymer and the substrate as it reduces mode leakage into the substrate and enhances modal gain. In contrast, a thin transparent electrode such as a metal oxide is preferable for the top electrode, where confinement is not a problem.Keywords
This publication has 11 references indexed in Scilit:
- Photonic band structure and emission characteristics of a metal-backed polymeric distributed feedback laserApplied Physics Letters, 2002
- Semiconducting (Conjugated) Polymers as Materials for Solid-State LasersAdvanced Materials, 2000
- A nearly diffraction limited surface emitting conjugated polymer laser utilizing a two-dimensional photonic band structureApplied Physics Letters, 2000
- Structures for organic diode lasers and optical properties of organic semiconductors under intense optical and electrical excitationsIEEE Journal of Quantum Electronics, 2000
- Lasers Based on Semiconducting Organic MaterialsAdvanced Materials, 1999
- Nonlinear emission and recombination in conjugated polymer waveguidesJournal of Applied Physics, 1999
- Study of lasing action based on Förster energy transfer in optically pumped organic semiconductor thin filmsJournal of Applied Physics, 1998
- A Flexible Conjugated Polymer LaserAdvanced Materials, 1998
- Semiconducting Polymers: A New Class of Solid-State Laser MaterialsScience, 1996
- Lasing from conjugated-polymer microcavitiesNature, 1996