WEB EXCLUSIVE: Organic semiconductor sources - Hybrid OLEDs combine vapor deposition with solution processing
Hybrid OLEDs made from polymeric and small-molecule materials combine the advantages of both material classes in one device, simplifying the production of OLEDs. Current organic-light-emitting-diode (OLED) device performance meets or exceeds the requirements for display applications. This environment, the development focus changes from performance improvement to optimizing the manufacturing process.
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Fig. 1 To produce cost-competitive OLEDs using current materials and processes, one option is to combine different approaches to OLED manufacturing. While OLEDs are traditionally produced using ultra-high-vacuum vapor deposition or solution processing, a hybrid device combines both methods. At first glance, this would seem to make OLED production more complicated, but there are a number of advantages in using this methodology.
The typical layer sequence of an OLED using Novaled's PIN structure—a pin sandwich of a p-doped layer, an insulator, and an n-doped layer—starts at the bottom with an inorganic anode that is usually made from indium tin oxide, or ITO (see Fig. 1). The organic layer stack consists of a doped hole-transport layer (HTL), blocking layers around the central light-emitting layer, and is finished by a doped electron-transport layer (ETL). Is typically made from an inorganic material such as silver.
Redox (reduction-oxidation) doping of organic transport layers with molecular dopants offers several advantages including low driving voltages, wide choice of materials for cathode and anode, and good power efficiency.1 Novaled's redox doping transport materials have long been used successfully for OLEDs in Recently, we investigated OLEDs in which some layers were deposited using solution processing. The hybrid OLEDs fall into two main categories: OLEDs in which only one layer is deposited by solution processing and the The subsequent OLED stack is deposited in vacuum, and OLEDs that have multiple solution-processed layers with only the final layer stack deposited in vacuum. Both approaches have specific advantages and challenges.
Read the complete article at Laser Focus World magazines web site. About the Author Ulrich Denker is a physicist at Novaled, Tatzberg 49, 01307 Dresden, Germany.![]()
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The typical layer sequence of an OLED using Novaled's PIN structure—a pin sandwich of a p-doped layer, an insulator, and an n-doped layer—starts at the bottom with an inorganic anode that is usually made from indium tin oxide, or ITO (see Fig. 1). The organic layer stack consists of a doped hole-transport layer (HTL), blocking layers around the central light-emitting layer, and is finished by a doped electron-transport layer (ETL). Is typically made from an inorganic material such as silver.
Redox (reduction-oxidation) doping of organic transport layers with molecular dopants offers several advantages including low driving voltages, wide choice of materials for cathode and anode, and good power efficiency.1 Novaled's redox doping transport materials have long been used successfully for OLEDs in Recently, we investigated OLEDs in which some layers were deposited using solution processing. The hybrid OLEDs fall into two main categories: OLEDs in which only one layer is deposited by solution processing and the The subsequent OLED stack is deposited in vacuum, and OLEDs that have multiple solution-processed layers with only the final layer stack deposited in vacuum. Both approaches have specific advantages and challenges.
Read the complete article at Laser Focus World magazines web site. About the Author Ulrich Denker is a physicist at Novaled, Tatzberg 49, 01307 Dresden, Germany.
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