Substrate - Page 7

Taiwas's ITRI (Industrial Technology Research Institute) has developed a new 6" flexible color AMOLED, using their FlexUPD technology. The display is just 0.01cm thick, and can continue to show images even when folded. The folding radius can reach 5cm or less, and the screen can be scrolled up to 15,000 times.

ITRI says that their FlexUPD technology is the simplest and cheapest technology for mass production paper-like displays. FlexUPD will be commercialized soon, and AUO plans to use it for flexible e-reader products "very soon".

Samsung plans to launch new AMOLEDs on a plastic substrate within two years. They say that these new AMOLEDs will be 'unbreakable'. They will also be lighter, safer and thinner. These qualities can be useful in mobile phone displays, which will allow Samsung to keep their AMOLED price premium in these years. Samsung plans to place a TFT on the plastic panel and to replace the existing vinyl protection sheet with PI (polyimide) film to avoid residue upon light emission.

Samsung revealed flexible, unbreakable AMOLED prototypes back in 2009, see video above.

The Printable Electronics Technology Centre (PETEC) has announced plans for a new prototyping line to support the lighting and Organic Photovoltaic sectors. The new line is targeted at industries needing large area coating capability alongside the need for reproducible uniform and low defectivity thin film coating onto glass and plastic substrates.

It is designed to be an automated batch tool based on cassette handling of samples to minimise manual intervention. The specification has been aligned with the needs of the SSL and PV industry. It will produce up to 20 samples per day with a panel size from 100mm to 200mm square. The line will have slot-die and spin coating modules, metal and organic evaporation and encapsulation.  It will enable the deposition of solution and small molecule OLED material technologies. It will target fine coating active layers of 10-200nm thinness with uniformity of +-5% across the full panel width.

Last week we reported that PolyPhotonix plans to launch a 8" 60lm/W OLED Lighting panel. They will be using this line at PETEC.

The Flexible Display Center (FDC) at Arizona State University announced that Sunic System has become an industry partner in the center. The FDC, together with Sunic, will develop flexible OLED displays. The FDC has purchased a Gen-II OLED SUNICEL Plus 400 vacuum evaporation and encapsulation process tool from Sunic for its Tempe development facility.The tool will be installed in the fall (2010), with first devices anticipated in 1Q 2011.

The SUNICEL Plus system is designed to simplify OLED technology development and manufacturing, and is equipped to handle plastic substrates without interrupting the vacuum process. The system enables full color AMOLED and mono-color panel production with high electro luminescence (EL) performance and long lifetime.

InnoPhysics has performed successful feasibility studies at the Holst Centre, and now is ready to go to market with its proprietary Digital-on-Demand PlasmaPrint hardware solution. They say that their technology enables software patterned surface functionalization, etching and deposition of functional coatings on thin (plastic) substrates.

Plasma-printed OLED lighting test structures

The proprietary InnoPhysics technology solution operates on a large variety of plastic substrates in ambient conditions, at room temperature and it provides flexibility in patterning, i.e. mask-less. As part of the go-to-market strategy, InnoPhysics is developing a PlasmaPrint toolkit integratable with existing table-top R&D print platforms.

The Holst Centre has released a new proprietary roll-to-roll (R2R) sintering platform for fast and low-temperature curing of printed conductive structures. The center is progressing towards a complete tool set for R2R manufacturing and can be used for plastic electronics such as flexible OLEDs, organic PV solar cells and more. Holst' line now includes printing, coating, drying and lamination stages in addition to the new sintering unit. A vacuum deposition stage is currently in development.

Screen printed structures on foil photo

High web speeds and low temperatures are key elements for R2R manufacturing of plastic electronics. The sintering platform uses a new photonic sintering process, developed by Holst Centre, which heats only the printed target material rather than the whole carrier substrate. The tool can sinter printed conductive structures in less than a second, which is already enabling a fast throughput speed of over 5 meters/minute. It also works at significantly lower temperatures than traditional sintering techniques, preventing distortion of the carrier substrates and reducing energy costs.

Researchers at Stanford University have successfully developed a brand new concept of OLEDs with a few nanometer of graphene as transparent conductor. This paved the way for inexpensive mass production of OLEDs on large-area low-cost flexible plastic substrate, which could be rolled up like wallpaper and virtually applied to anywhere you want. The researchers say that Graphene has the potential to be transparent, high-performance, highly conductive and cheaper by several orders of magnitude than current ITO based solutions. Interestingly just a few weeks ago we reported that Graphene can be used to make organic lighting devices, too.

Graphene OLED

Traditionally, indium tin oxide (ITO) is used in OLEDs, but indium is rare, expensive and difficult to recycle. Scientists have been actively searching for an alternative candidate.

The next generation of optoelectronic devices requires transparent conductive electrodes to be lightweight, flexible, cheap, environmental attractive, and compatible with large-scale manufacturing methods. Graphene (a single layer of graphite) is becoming a very promising candidate due to its unique electrical and optical properties. Very recently, Junbo Wu et al., researchers at Stanford University, successfully demonstrated the application of graphene in OLEDs for the first time.

A Japanese consortium of 13 companies (including Sharp and Hitachi) claims that they found a way to make LCDs using plastic film instead of a glass substrate. This means that those displays can be very thin and flexible. They do admit however that this is a very complicated process. They have shown a 3.5" bendable color LCD that just 0.49mm thick and weights 7 grams. They hope to make a better display by 2012, and use this technology to mass produce thin, curved LCD displays.

The companies say that the new manufacturing process is simpler than the one used in current LCDs, and also the new displays will consumer 70% less energy!

The Fraunhofer IPMS announced plans to set up roll-to-roll OLED equipment for 30cm-wide metal foil substrate in December. The new equipment will allow films to be formed continuously. The institute does not have any encapsulation equipment yet.

Nippon Electric Glass is showing the world's slimmest OLED Lighting panel - only 100 micrometer thick, using their ultra-slim glass substrate. They say that the panel has a high-level gas barrier properties, and that it can be easily bent.