Title :
Silicon compatible organic light emitting diode
Author :
Kim, Helen H. ; Miller, Timothy M. ; Westerwick, Eric H. ; Kim, Young O. ; Kwock, Elizabeth W. ; Morris, M.D. ; Cerullo, M.
Author_Institution :
AT&T Bell Labs., Holmdel, NJ, USA
fDate :
12/1/1994 12:00:00 AM
Abstract :
As an effort toward a goal of monolithic optoelectronics for silicon (Si) chip-to-chip connections, we have fabricated organic light emitting diodes (LED´s) using either heavily N-doped silicon (Si) as a cathode or P-doped Si as an anode. A thin silicon dioxide (SiO2 ) layer, thermally grown on Si before deposition of a polymer or a molecular organic layer, enhances the electron injection into the semiconducting emissive layer. Without the thin oxide layer, no light was observed from LED´s made from either (2-methoxy, 5-(2´-ethyl-hexoxy)-1, 4-phenylene vinylene) (MEH-PPV) or 8-hydroxyquinoline aluminum (Alq). With the SiO2 layer,the internal quantum efficiencies as high as 0.02% and 0.5% have been observed for MEH-PPV and Alq, respectively, and the turn-on voltages were as low as 2.5 V and 8 V, again for MEH-PPV and Alq, respectively. From the LED response time measurement, we identified RC constant and the recombination time of transport-related traps as the speed limiting factors
Keywords :
anodes; cathodes; emissivity; integrated optoelectronics; light emitting diodes; optical interconnections; organic compounds; semiconductor thin films; 0.02 percent; 0.5 percent; 2-methoxy, 5-(2´-ethyl-hexoxy)-1, 4-phenylene vinylene; 2.5 V; 8 V; 8-hydroxyquinoline aluminum; LED; P-doped Si; Si; Si chip-to-chip connections; SiO2; SiO2 layer; anode; cathode; deposition; electron injection; heavily N-doped silicon; internal quantum efficiencies; molecular organic layer; monolithic optoelectronic; organic light emitting diodes; polymer; semiconducting emissive layer; silicon compatible organic light emitting diode; thermally grown; thin oxide layer; thin silicon dioxide layer; turn-on voltages; Aluminum; Anodes; Cathodes; Electrons; Light emitting diodes; Low voltage; Organic light emitting diodes; Polymers; Semiconductivity; Silicon compounds;
Journal_Title :
Lightwave Technology, Journal of
