Organic lighting research burns bright

The long, challenging technological march from the low-power light bulb Thomas Edison invented to the ultimate in a bright and energy-efficient lighting device may reach fruition in work led by the two ASU researchers.

A recent cover story in the journal Advanced Materials, a leading materials and device engineering research publication, details advances in the use of organic light-emitting diodes (OLEDs) by Ghassan Jabbour and Jian Li, with help from graduate students Evan Williams and Kirsi Haavisto, a Fulbright scholar from Finland.

Jabbour is a professor and Li is an assistant professor in the new ASU School of Materials, which is jointly administered by the Ira A. Fulton School of Engineering and the College of Liberal Arts and Sciences. Jabbour also is director of optoelectronics research and development at the Flexible Display Center at ASU.

The two have developed an organic lighting device with “100 percent internal quantum efficiency” by employing newly designed host materials coupled with optimized device architecture.

Internal quantum efficiency involves the number of photons generated inside the device per each electron from the electricity source – such as a battery.

What's particularly significant about the researchers' work is that their optimized device adopts an even simpler structure than any yet reported by other research groups.

“There is no waste of electricity,” Jabbour says. “All the current you are putting into the device is being used to produce light. It's the first time something like this has been demonstrated. Nobody else has shown a 100 percent internal quantum efficiency for lighting devices using a single molecular dopant to emit white light.”

The achievement promises significant progress in the development of solid-state lighting based on OLED technology that can be manufactured at low costs.

Such devices also could provide a major source for progress in global environmental efforts to conserve energy and natural resources. In addition to progress in energy conservation, the work also could accelerate advances in semiconductor technology materials through improvements in low-power organic thin-film transistors, an area Jabbour and Li's group is researching intensely.

Source: Arizona State University

Related stories:

Scuppering pirates improves internet audio
A new digital watermarking system not only protects music and media files from online pirates but also ensures that the quality for legitimate users is as good as it gets.
New Nanowire-Based Memory Could Beef Up Information Storage
Researchers from the University of Pennsylvania have created a type of nanowire-based information storage device that is capable of storing three bit values rather than the usual two—that is, "0," "1," and "2" instead of just "0" and "1." This ability could lead to a new generation of high-capacity information storage for electronic devices.
Pocket-sized magnetic resonance imaging
The term “MRI scan” brings to mind the gigantic, expensive machines that are installed in hospitals. But research scientists have now developed small portable MRI scanners that perform their services in the field: for instance to examine ice cores.
Tufts to develop morphing 'chemical robots'
Tufts University has received federal funding to develop chemical robots that will be able to squeeze into spaces as tiny as 1 centimeter, then morph into something 10 times larger, and ultimately biodegrade. The "chembots" could access urban environments, tunnels, caves and debris fields, and carry out other risky operations in complex environments.
Could better spin injection lead to a quantum information device?
One of the more promising types of materials for use in spintronics today is the class of metal alloys known as Heusler alloys. These alloys are named after a German engineer, and might be useful in technology in which electron quantum spin states are used to enhance electronic devices. Additionally, Heusler alloys may have an effect in quantum memory processing and telecommunications.
Airless tire project may prove a lifesaver in military combat
Rarely does one come across a business where the phrase “reinventing the wheel” is not just a metaphor, it’s an operating principle.
‘Electron Trapping’ May Impact Future Microelectronics Measurements
Using an ultra-fast method of measuring how a transistor switches from the “off” to the “on” state, researchers at the National Institute of Standards and Technology (NIST) recently reported that they have uncovered an unusual phenomenon that may impact how manufacturers estimate the lifetime of future nanoscale electronics.


Super-sensitive explosives detector can detect explosives at distances exceeding 20 yards
Using a laser and a device that converts reflected light into sound, researchers at the Department of Energy's Oak Ridge National Laboratory can detect explosives at distances exceeding 20 yards.

News discussion:

Production in Physics news