MONTREAL, Jan. 11, 2012 /ATR-Newswire/  ELECTRONICS.CA PUBLICATIONS, the electronics industry market research and knowledge network, announces the release of a comprehensive report on OLED Technology. Organic light emitting diodes (OLED) technology advanced rapidly in 2011, a trend that will continue through this decade. OLED technology has progressed in areas including organic materials, color patterning, electronic driving methods, and encapsulation. However, the ability to scale OLED display manufacturing to fabs larger than the current Gen 5.5 has yet to be demonstrated, and the cost of larger panels is not yet clear.

OLED emerged in the 1980s from laboratories at Eastman Kodak in the US and Cambridge University in the UK, and was first commercialized in the late 1990s. Enthusiasm has increased recently as Samsung Mobile Displays has started manufacturing active matrix OLED (AMOLED) displays in a Gen 5.5 fab and announced plans to build a Gen 8 fab (as did LG Display), and several other suppliers entered or re-entered OLED display manufacturing, including AUO, CMI, IRICO, Tianma, and BOE.

The OLED Technology Report details how OLEDs offer a solid-state solution for displays, lighting, and organic electronics. OLED displays can provide high contrast ratio, fast response time, wide color gamut, and wide viewing angle, while operating in a broad temperature range at low power consumption. In addition, OLED technology enables thin devices that can be both flexible and transparent.

OLED display revenues are estimated to exceed $4 billion in 2011 (approximately 4% of flat panel display revenues), and are forecast to reach more than $20 billion (approximately 16% of the total display industry by 2018. In addition, OLED lighting gained momentum in 2011, and is forecast to reach revenues of approximately $6 billion by 2018.

OLED displays operate through direct emission, as opposed to transmissive LCD or reflective displays, which enables area lighting. The technology has made good progress and is ready to enter large-size applications, but low cost manufacturing for large sizes is still a challenge.

OLED is now a mass-market technology in small/medium displays, particularly in smart phone applications. Investments in Gen 8 (2200 × 2500 mm) fabs indicate that AMOLED will compete in larger size applications, such as in TV and mobile PCs, within two years. Samsung released a 7.7” AMOLED tablet PC in December 2011, and more tablet and other mobile PCs are expected in 2012. LG is expected to enter the market in 2012 with a 55” AMOLED TV. With technology improvements, the report forecasts AMOLED will enter other applications as well.

While nearly all AMOLEDs on the market are currently based on LTPS, several companies are developing AMOLEDs using oxide or a-Si TFT backplanes, and are likely to start production in 2012.

Table 1: Comparison of LTPS, a-Si, and Oxide TFT for AMOLED

Characteristic	LTPS	a-Si	Oxide TFT
Electron mobility	Excellent 10‑500 cm²/VS	Poor 0.5 cm²/VS	Good 1-40 cm²/VS
Uniformity	Poor	Excellent	Good with amorphous type, poor with crystalline type
Stability	Excellent	Poor	Poor
Scalable	Limited to <40”	Excellent, >100”	Potential to 100”
Process temp	High >400°C	Typical ~300°C, some low temp process can be ~150°C	Typical ~200°C, but some anneal at 350°C
Cost	High	Low	Medium
Availability	Yes MP	Demo for AMOLED; Announced by RiTdisplay and IGNIS; MP by end of 2011	Demo for AMOLED; MP estimated by end of 2012
Challenges	Uniformity, cost, scalability	Poor mobility; poor stability	Threshold voltage unstable; manufacturing process not mature

The OLED Technology Report includes some other key findings:

• Organic materials of all types have efficacies ranging from less than 10 to nearly 100 cd/A. Large increases in efficiency have been obtained with phosphorescent materials, especially in red and green.
• Nearly all AMOLED displays are made using thermal evaporation through a fine metal mask (FMM) for color patterning. However, this method has low material utilization and is limited to small substrate sizes. Manufacturing processes with higher material utilization and better uniformity, such as linear and area sources, are likely to be adopted.
• Other color patterning methods, such as white with color filter and solution-processed materials, are also evolving and ready to be adopted for mass production in larger generation fabs.

The 500+ page OLED Technology Report provides a detailed discussion on the rapid growth and adoption of OLED technology.  This comprehensive report provides historical data on OLED technology, organic material development, electronic driving types (passive matrix, LTPS TFT, a-Si TFT, Oxide TFT, organic TFT, etc.), color patterning methods, capacity analysis and a market forecast through 2018. The report provides detailed analysis on different solutions for the bottleneck in mass production for OLED color patterning. This report also discusses the current status of the OLED industry, developers in each region, and new opportunities.

Details of the new report, table of contents and ordering information can be found on Electronics.ca Publications' web site.  View the report: OLED Technology Report.