A. Romanov, D. Di, Le Yang, P. Conaghan, Saul T. E. Jones, R. Friend, Mikko Linnolahti, D. Credgington, M. Bochmann
{"title":"线性碳金属酰胺作为高效溶液处理和气相沉积oled的新型发射体(会议报告)","authors":"A. Romanov, D. Di, Le Yang, P. Conaghan, Saul T. E. Jones, R. Friend, Mikko Linnolahti, D. Credgington, M. Bochmann","doi":"10.1117/12.2320824","DOIUrl":null,"url":null,"abstract":"Current materials leaders in OLED technology are largely based on phosphorescent iridium complexes and Thermally Activated Delayed Fluorescence (TADF) materials which emit by harvesting light from all excited states ensuring nearly 100% internal quantum efficiency (IQE). Although, high efficiency red, green and blue OLEDs were realized, very short operating stability remains a fundamental challenge for blue OLEDs. Here we present our materials design strategy.\nWe have recently designed numerous linear coinage metal complexes with efficient photo- and electroluminescent properties.[1,2] Our materials are composed of the donor and acceptor ligands which are linked by a coinage metal atom. Linear geometry of coinage metal complexes enables rotational flexibility. Rotation about the metal-ligand bond allowed us to tune the energy gap between singlet and triplet excited states. When the gap is close to zero, facile intersystem crossing and reversed intersystem crossing are possible which enables efficient singlet and triplet excited state harvesting. Depending on the value of the energy gap we have designed various functional materials with phosphorescent or delayed fluorescence properties. As a proof of concept, we fabricated OLED devices with exceptionally high external quantum efficiencies (>28% EQE) in both solution-processed and vacuum-deposited OLEDs.[3] Power and current efficiency are comparable to or exceeding state-of-the-art phosphorescent OLEDs and quantum dot LEDs. Our materials possess short excited state lifetime (100-300 ns) for the delayed emission which is highly important for the fabrication of the long-lived OLEDs.\n[1] A.S. Romanov, D. Di, L. Yang, J. Fernandez-Cestau, C.R. Becker, C.E. James, B. Zhu, M. Linnolahti, D. Credgington, M. Bochmann, Chem. Commun., 52, 6379 (2016)\n[2] A.S. Romanov, C.R. Becker, C.E. James, D. Di, D. Credgington, M. Linnolahti, M. Bochmann, Chem. Eur. J., 23, 4625 (2017).\n[3] D. Di, A.S. Romanov, L. Yang, J.M. Richter, J.P.H. Rivett, S. Jones, T.H. Thomas, M.A. Jalebi, R.H. Friend, M. Linnolahti, M. Bochmann, D. Credgington, Science, 356, 159 (2017)","PeriodicalId":158502,"journal":{"name":"Organic Light Emitting Materials and Devices XXII","volume":"16 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2018-09-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Linear carbene metal amides as a new class of emitters for highly efficient solution-processed and vapor-deposited OLEDs (Conference Presentation)\",\"authors\":\"A. Romanov, D. Di, Le Yang, P. Conaghan, Saul T. E. Jones, R. 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引用次数: 0
摘要
目前OLED技术的领军材料主要基于磷光铱配合物和热激活延迟荧光(TADF)材料,这些材料通过收集所有激发态的光来发射,确保近100%的内部量子效率(IQE)。虽然已经实现了高效率的红、绿、蓝oled,但对于蓝oled来说,非常短的工作稳定性仍然是一个根本性的挑战。在这里,我们提出了我们的材料设计策略。我们最近设计了许多具有高效光致发光和电致发光特性的线性铸币金属配合物。[1,2]我们的材料是由一个金属原子连接的给体和受体配体组成的。铸币金属配合物的线性几何结构使其具有旋转灵活性。围绕金属配体键的旋转使我们能够调整单线态和三重态激发态之间的能隙。当间隙接近于零时,系统间可以轻松穿越和反向穿越,从而实现有效的单重态和三重态激发态收获。根据能隙的大小,我们设计了各种具有磷光或延迟荧光特性的功能材料。作为概念验证,我们在溶液处理和真空沉积的OLED中制造了具有极高外部量子效率(>28% EQE)的OLED器件功率和电流效率与最先进的磷光oled和量子点led相当或超过。我们的材料具有较短的延迟发射激发态寿命(100-300 ns),这对制造长寿命oled非常重要A.S. Romanov, D. Di, L. Yang, J. Fernandez-Cestau, C.R. Becker, C.E. James, B. Zhu, M. Linnolahti, D. Credgington, M. Bochmann, Chem。Commun。[10]刘建军,刘建军,刘建军,刘建军,刘建军,等。欧元。[J] .中国生物医学工程学报,2017,46 (5):444 - 444D. Di, A.S. Romanov, L. Yang, J.M. Richter, J.P.H. Rivett, S. Jones, T.H. Thomas, M.A. Jalebi, R.H. Friend, M. Linnolahti, M. Bochmann, D. Credgington, Science, 356, 159 (2017)
Linear carbene metal amides as a new class of emitters for highly efficient solution-processed and vapor-deposited OLEDs (Conference Presentation)
Current materials leaders in OLED technology are largely based on phosphorescent iridium complexes and Thermally Activated Delayed Fluorescence (TADF) materials which emit by harvesting light from all excited states ensuring nearly 100% internal quantum efficiency (IQE). Although, high efficiency red, green and blue OLEDs were realized, very short operating stability remains a fundamental challenge for blue OLEDs. Here we present our materials design strategy.
We have recently designed numerous linear coinage metal complexes with efficient photo- and electroluminescent properties.[1,2] Our materials are composed of the donor and acceptor ligands which are linked by a coinage metal atom. Linear geometry of coinage metal complexes enables rotational flexibility. Rotation about the metal-ligand bond allowed us to tune the energy gap between singlet and triplet excited states. When the gap is close to zero, facile intersystem crossing and reversed intersystem crossing are possible which enables efficient singlet and triplet excited state harvesting. Depending on the value of the energy gap we have designed various functional materials with phosphorescent or delayed fluorescence properties. As a proof of concept, we fabricated OLED devices with exceptionally high external quantum efficiencies (>28% EQE) in both solution-processed and vacuum-deposited OLEDs.[3] Power and current efficiency are comparable to or exceeding state-of-the-art phosphorescent OLEDs and quantum dot LEDs. Our materials possess short excited state lifetime (100-300 ns) for the delayed emission which is highly important for the fabrication of the long-lived OLEDs.
[1] A.S. Romanov, D. Di, L. Yang, J. Fernandez-Cestau, C.R. Becker, C.E. James, B. Zhu, M. Linnolahti, D. Credgington, M. Bochmann, Chem. Commun., 52, 6379 (2016)
[2] A.S. Romanov, C.R. Becker, C.E. James, D. Di, D. Credgington, M. Linnolahti, M. Bochmann, Chem. Eur. J., 23, 4625 (2017).
[3] D. Di, A.S. Romanov, L. Yang, J.M. Richter, J.P.H. Rivett, S. Jones, T.H. Thomas, M.A. Jalebi, R.H. Friend, M. Linnolahti, M. Bochmann, D. Credgington, Science, 356, 159 (2017)
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