New Dendritic Materials as Potential OLED Transport and Emitter Moeities

Autor:	Charles W. Spangler, Asanga B. Padmaperuma, Sanjini Nanayakkara, Linda S. Sapochak, Benjamin D. Reeves, L. Madrigal, Daniel Fogarty, Greg Schmett, K. Ashworth, Nancy M. Washton
Rok vydání:	2000
Předmět:	chemistry.chemical_classification Materials science business.industry Aromatic amine Electron transport chain chemistry Thermal OLED Optoelectronics Charge carrier business Joule heating Glass transition Common emitter
Zdroj:	MRS Proceedings. 621
ISSN:	1946-4274 0272-9172
DOI:	10.1557/proc-621-q3.9.1
Popis:	Traditionally, organic light-emitting devices (OLEDs) are prepared with discrete layers for hole and electron transport. Different materials must be used for these layers because most materials will preferentially transport one charge carrier more efficiently than the other. In most cases, the emitter material serves a dual purpose as both the emitter and the hole or electron transporter. One of the major failure modes of OLEDs results from thermal instabilities of the insulating organic layers caused by joule heating during device operation. The problem is most pronounced for the hole transporting layer (HTL) material which are usually tertiary aromatic amines (i.e., TPD and NPD). This has been attributed to the relatively lower glass transition temperatures (Tg) and resulting inferior thermal stabilities compared to the other materials making up the device. Many researchers have produced HTL materials with higher Tgs based on tertiary aromatic amine oligomers and starburst compounds. Starburst or model dendritic materials offer the advantages of high thermal stabilities and multi-functionality.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::2f2e9b8f128dac78e8bf65e2546c88ac https://doi.org/10.1557/proc-621-q3.9.1 Zobrazit plný text záznamu Full text from SpringerLink