A. S. Burlov, V. G. Vlasenko, D. A. Garnovskii, A. I. Uraev, Yu. V. Koshchienko, E. I. Mal’tsev, D. A. Lypenko, A. V. Dmitriev
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引用次数: 0
Abstract
The article represents a translated, revised, and updated Section 6.3 of the monograph by A.S. Burlov, V.G. Vlasenko, D.A. Garnovskiy, A.I. Uraev, E.I. Maltsev, D.A. Lypenko, and A.V. Vannikov, Electroluminescent Organic Light-Emitting Diodes Based on Metal Coordination Compounds, Rostov-on-Don: Yuzhn. Fed. Univ., 2015; ISBN 978-5-9275-1469-4 (see Additional Information). This section is dedicated to reviewing the photoluminescence and electroluminescence properties of metal complexes based on bi- and polydentate ligands of the azomethine type (Schiff bases). Many metal complexes of Schiff bases find wide use as luminescent materials. One of the applications of these compounds is the use as emissive layers or dopants for manufacturing OLED. The photo- and electroluminescence properties of a series of the metal complexes with the ligands based on the derivatives of hydroxybenzaldehyde, 2-(N-tosylamino)benzaldehyde, 1‑phenyl-3-methyl-4-formylpyrazol-5-one, and some others are reviewed. The systematic categorization of these compounds extends beyond their photophysical properties to consider the electroluminescence characteristics observed in OLED devices employing them as the basis. By modifying known azomethine-type ligand systems, one can obtain metal complex compounds with exceptional thermal stability, solubility, and quantum efficiency. These characteristics enable their use as luminescent materials in highly efficient OLED devices.
Abstract The article represents a translated, revised, and updated Section 6.3 of the monograph by A.S. Burlov, V.G. Vlasenko, D.A. Garnovskiy, A.I. Uraev, E.I. Maltsev, D.A. Lypenko, and A.V. Vannikov, Electroluminescent Organic Light-Emitting Diodes Based on Metal Coordination Compounds, Rostov-on-Don: Yuzhn.Fed.Univ.,2015;ISBN 978-5-9275-1469-4(参见附加信息)。本节专门评述基于偶氮甲烷型双齿和多齿配体(希夫碱)的金属配合物的光致发光和电致发光特性。许多希夫碱金属配合物被广泛用作发光材料。这些化合物的应用之一是用作制造有机发光二极管的发光层或掺杂剂。本文综述了一系列金属配合物的光致发光和电致发光特性,这些金属配合物的配体基于羟基苯甲醛、2-(N-对甲苯磺酸氨基)苯甲醛、1-苯基-3-甲基-4-甲酰基吡唑-5-酮和其他一些衍生物。对这些化合物进行系统分类时,不仅考虑了它们的光物理特性,还考虑了以它们为基础的有机发光二极管设备中观察到的电致发光特性。通过修改已知的偶氮甲烷型配体系统,可以获得具有优异热稳定性、溶解性和量子效率的金属复合物。这些特性使它们能够用作高效有机发光二极管设备的发光材料。
期刊介绍:
Russian Journal of Coordination Chemistry is a journal that publishes reviews, original papers, and short communications on all aspects of theoretical and experimental coordination chemistry. Modern coordination chemistry is an interdisciplinary science that makes a bridge between inorganic, organic, physical, analytical, and biological chemistry.
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