Skip navigation

Brighter, cheaper blue light could revolutionise screen technology

15th March 2024

Researchers have found a new way to simplify the structure of high-efficiency blue organic light-emitting diodes (OLEDs), which could lead to longer-lasting and higher definition television screens. 

OLEDs are a class of organic electronics that are already found commercially in smartphones and displays and can be more efficient than competing technologies.  

Although OLED television screens have vivid picture quality, they also have drawbacks such as high cost and comparatively short lifespans.   

In OLED displays, screen pixels are composed of three different coloured subpixels – red, green and blue – that light up at different intensities to create different colours. However, the subpixels that emit blue light are the least stable and can be susceptible to screen ‘burn-in’, which can discolour the screen and ruin viewing quality. 

In a paper published in Nature Materials, a team of researchers from Northumbria, Cambridge, Imperial and Loughborough universities describe a new design that overcomes these issues and may lead to simpler, less expensive systems with purer and more stable blue light. 

Their findings could lead to TV and smartphone screens using less energy in future, making them more efficient and sustainable. 

An OLED is built like a sandwich, with organic semiconductor layers between two electrodes. In the middle of the stack is the emissive layer, which lights up when powered with electricity. Electrical energy goes into the molecules, which then release this extra energy as light. 

An ideal OLED turns most of the electrical energy into light, but sometimes the energy gets diverted and degrades the structure of the OLED. This is especially a problem with blue light and reduces both the OLED efficiency and lifetime.

Caption: Dr Marc Etherington

Dr Marc Etherington, Assistant Professor in Molecular Photophysics  in Northumbria University’s Department of Mathematics, Physics and Electrical Engineering, researches the properties of organic semiconductors. He led a spectroscopic analysis of the triplet energies of the molecules to measure and gain a crucial understanding of how their energy transfer process works.  

Dr Etherington’s findings provide a key element to this study, helping the research team form a complete picture of the energy level arrangement. 

The research team designed a new light-emitting molecule that has shields added to block the destructive energy pathways and control how the molecules interact. 

 

 

This better understanding of how efficient a molecule in an OLED can be will inform how materials are designed and used in future, supporting the push towards higher device performance. 

Dr Etherington explained: “With this new molecule we have created a channel to develop more efficient OLEDs that will drive down the energy consumption of our devices in the information era. As we all work towards net zero targets, this could have a significant impact for both manufacturers and consumers.” 

Co-corresponding author Dr Daniel Congrave, from the University of Cambridge, who led the material design and synthetic work alongside Prof. Hugo Bronstein, said: “OLED screens have great picture quality and carry a high premium. However, OLED TVs don’t last as long as other screens. 

“Pixels that emit blue light are essential for a practical display but are also where the problems lie. We’ve designed a molecule that’s allowed us to simplify the emissive layer of the blue pixel to only two components, while maintaining high efficiency, which could help to drive down cost.  

“The molecule we describe in this paper is also one of the narrowest emitting blue molecules out there, which is very useful for screens because it allows for high colour purity.” 

Co-first author Dr Hwan-Hee Cho, a postdoctoral researcher in Professor Richard Friend’s group in the University of Cambridge Cavendish Laboratory, designed the OLED devices. Cho said: “This research will contribute to the next generation of blue OLEDs that achieve high efficiency, brightness, stability, and colour purity simultaneously. 

Northumbria University researchers are specialising in developing new energy materials and systems to help deliver a cleaner, greener future. Using fundamental physics, chemistry and engineering, they are creating new ways of generating and storing renewable energy to help reach net zero targets.  

The paper Suppression of Dexter Transfer by Covalent Encapsulation for Efficient Matrix-Free Narrowband Deep Blue Hyperfluorescent OLEDs, is now published in Nature Materials



Credits for imagery used: 
Blue banner image at top of page - a solution of the new molecule glowing under UV light: Craig Yu and Petri Murto
Video: Petri Murto

Energy Systems and Materials

Our energy materials and systems research uses fundamental physics, chemistry and engineering to develop new ways to generate and store renewable energy - to help deliver a cleaner and greener future.

News and Features

This is the place to find all the latest news releases, feature articles, expert comment, and video and audio clips from Northumbria University

a sign in front of a crowd
+

Northumbria Open Days

Open Days are a great way for you to get a feel of the University, the city of Newcastle upon Tyne and the course(s) you are interested in.

Research at Northumbria
+

Research at Northumbria

Research is the life blood of a University and at Northumbria University we pride ourselves on research that makes a difference; research that has application and affects people's lives.

NU World
+

Explore NU World

Find out what life here is all about. From studying to socialising, term time to downtime, we’ve got it covered.


Latest News and Features

a map showing areas of ice melt in Greenland
S2Cool project lead Dr Muhammad Wakil Shahzad
The Converted Flat in 2049, by the Interaction Research Studio, is one of seven period rooms built as part of the Real Rooms project which opened in July at the Museum of the Home in London.
The UK Centre for Polar Observation and Modelling (CPOM), based at Northumbria University, has been awarded over £400,000 by the European Space Agency to investigate tipping points in the Earth’s icy regions with a focus on the Antarctic. Photo by Professor Andrew Shepherd.
Nature Awards Inclusive Health Research
Some members of History’s editorial team (from left to right): Daniel Laqua (editor-in-chief), Katarzyna Kosior (reviews editor), Lewis Kimberley (editorial assistant), Charotte Alston (deputy editor) and Henry Miller (online editor).
Dr Elliott Johnson, Vice Chancellor’s Fellow in Public Policy at Northumbria University.
Balfour Beatty graduates at Northumbria's winter congregation

Back to top