Electroluminescence mechanisms in organic light emitting devices employing a europium chelate doped in a wide energy gap bipolar conducting host
暂无分享,去创建一个
[1] Rikken. Spontaneous emission from stratified dielectrics. , 1995, Physical review. A, Atomic, molecular, and optical physics.
[2] Yuji Hamada,et al. Novel Europium Complex for Electroluminescent Devices with Sharp Red Emission , 1995 .
[3] C. C. Wu,et al. Poly(p‐phenylene vinylene)/tris(8‐hydroxy) quinoline aluminum heterostructure light emitting diode , 1995 .
[4] Vojislav I. Srdanov,et al. Narrow Bandwidth Luminescence from Blends with Energy Transfer from Semiconducting Conjugated Polymers to Europium Complexes , 1999 .
[5] M. El-Sayed,et al. Mechanism and Rate of the Intramolecular Energy Transfer Process in Rare‐Earth Chelates , 1965 .
[6] Digby F. Williams,et al. Carrier‐Exciton Interactions in Crystalline Anthracene , 1972 .
[7] Runguang Sun,et al. Temperature-dependent electroluminescence from (Eu, Gd) coordination complexes , 1997 .
[8] J. R. Leto,et al. Photoluminescence of Lanthanide Complexes. II. Enhancement by an Insulating Sheath , 1964 .
[9] K. Seki,et al. Energy level alignment at organic/metal interfaces studied by UV photoemission , 1997 .
[10] Hermi F. Brito,et al. Experimental and theoretical emission quantum yield in the compound Eu(thenoyltrifluoroacetonate)3.2(dibenzyl sulfoxide) , 1998 .
[11] Stephen R. Forrest,et al. Relationship between electroluminescence and current transport in organic heterojunction light‐emitting devices , 1996 .
[12] A. Kahn,et al. Band alignment at organic-inorganic semiconductor interfaces: α-NPD and CuPc on InP(110) , 1999 .
[13] Yoshiharu Sato,et al. Effect of aromatic diamines as a cathode interface layer , 1997 .
[14] R. E. Whan,et al. Luminescence studies of rare earth complexes: Benzoylacetonate and dibenzoylmethide chelates , 1962 .
[15] S. Forrest,et al. VERY HIGH-EFFICIENCY GREEN ORGANIC LIGHT-EMITTING DEVICES BASED ON ELECTROPHOSPHORESCENCE , 1999 .
[16] I. Zschokke-gränacher,et al. Exciton–charge carrier interactions in the electroluminescence of crystalline anthracene , 1975 .
[17] 敬三 平木,et al. ユウロピウム,サマリウム-β-ジケトン錯体の螢光特性とその螢光分析への応用 , 1981 .
[18] T. Skotheim,et al. Red electroluminescence from a thin organometallic layer of europium , 1996 .
[19] Katsutoshi Nagai,et al. Bright red light‐emitting organic electroluminescent devices having a europium complex as an emitter , 1994 .
[20] J. Kido,et al. Organic electroluminescent devices using lanthanide complexes , 1993 .
[21] M. Lampert,et al. Current injection in solids , 1970 .
[22] Shui-Tong Lee,et al. Improved performance of electroluminescent devices based on an europium complex , 2000 .
[23] W. Messier,et al. Episodic adaptive evolution of primate lysozymes , 1997, Nature.
[24] H. Brito,et al. Spectroscopic properties of a new light-converting device Eu(thenoyltrifluoroacetonate)3 2(dibenzyl sulfoxide). A theoretical analysis based on structural data obtained from a sparkle model , 1997 .
[25] Tetsuo Tsutsui,et al. Confinement of charge carriers and molecular excitons within 5‐nm‐thick emitter layer in organic electroluminescent devices with a double heterostructure , 1990 .
[26] Dongxu Zhao,et al. Spectrally-narrow blue light-emitting organic electroluminescent devices utilizing thulium complexes , 1999 .
[27] Shin-ichiro Tamura,et al. A Blue Organic Light Emitting Diode , 1999 .
[28] Tetsuo Tsutsui,et al. Sharply directed emission in organic electroluminescent diodes with an optical-microcavity structure , 1994 .
[29] S. Forrest,et al. Highly efficient phosphorescent emission from organic electroluminescent devices , 1998, Nature.