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ITRI Reports Breakthrough in OLED Lifetime

Taiwan-based ITRI has reported the development of a new OLED device architecture that significantly increases the lifetime of RGB OLED displays. The new structure, called a Plasmon-Coupled Organic Light Emitting Diode (PCOLED), boosts the lifetime by 27 times, compared to the conventional blue fluorescent/red & green phosphorescent structure.

The figure below shows the PCOLED architecture compared to the traditional one. In the conventional architecture, red and green phosphorescent layers are stacked on top of a blue fluorescent layer to emit white light. However, the blue fluorescent layer
has poor efficiency and lifetime, which limits the overall device lifetime.

The PCOLED replaces the blue fluorescent layer with a green phosphorescent layer with a new double metal structure. This configuration emits blue light, and since it is based on the green fluorescent material, the lifetime of the device is greatly increased.

PC OLED DNL structure

In a conversation with Dr. Ming-Shan Jeng of the Intelligent Energy-Saving System Division at ITRI, we first asked him to explain what a plasmon is.

“In a conventional organic-metal interface of an OLED, there is a collective oscillation of electrons, called surface plasmon, created by electromagnetic waves travelling through the interface,” explained Dr. Jeng. “Normally, the TM component is
converted to surface plasmons and the TE component passes through. In optical terms, the interface acts like a polariser, so 50% of the light is lost to plasmons as heat.”

“In the green phosphorescent material, there is actually a blue emission band in addition to the green one, but it is very weak. With the double metal structure, we actually generate more plasmons and shift the probability for emission from the green
to the blue band. This is not an upconversion process but merely a change in conditions within the green material,” said Dr. Jeng.

Dr. Jeng explained that this condition was discovered by accident when they were doing another experiment on light out-coupling and saw some blue emission. As they dug deeper, they realized the potential of the discovery and so focused on developing the
PCOLED technology.

To date, they have developed 10×10 and 15x15cm samples. The characteristics of the blue light and materials are shown in the table.

PC OLED table2

Dr. Jeng noted that ITRI’s role is to develop technology and seek commercial partners. This typically takes the form of a license and royalty model. So far, ITRI is working with a local company, named WiseChip, to begin commercialisation of the PCOLED
structure on a passive matrix OLED line. Passive matrix technology is easier to manufacture than active matrix, so it made sense to begin commercialisation efforts with the easier process.

Dr. Jeng says that the same equipment can be used and no new equipment is needed for PCOLED. Naturally, the materials and processes change, but this change is reversible, he thinks.

The substrates for this line are small and the first prototypes have just been completed based on this modified line. However, it is likely to be another 1-2 years before commercial products appear.

It should also be noted that this is a vacuum deposition OLED manufacturing process so it may be better suited in the short term for display, as it is likely too expensive for general lighting. But Dr. Jeng is already thinking about solution processing
as well, which has the potential for much lower costs. He hopes to start a program on this in a few years. – CC