According to those involved it could enable screens and electronic devices to become thinner, offer higher resolution and be much more energy efficient.
The team, which comprised of researchers from Nottingham Trent University, the Australian National University and the University of New South Wales Canberra in Australia have been able to engineer electrically tuneable arrays of nanoparticles called ‘metasurfaces’ which can offer significant benefits over current liquid crystal displays.
While the current display market offers a large range of choices, each comes with its own pros and cons. However, factors including production costs, lifespan and energy consumption have kept liquid crystal technology the most dominant and popular technology for screens such as TV sets and monitors.
Liquid crystal cells are responsible for switching the transmitted light on and off and are lit by a backlight, with polarising filters in the front and behind the pixels. They determine the dimension of pixels – the resolution – and play a significant role in managing the device’s power consumption.
The metasurface cells that have been developed, and which have tunability and extraordinary light scattering properties, would replace the liquid crystal layer and would not require the polarisers, which are responsible for a large amount of wasted light intensity and energy use in displays.
The metasurfaces are 100-times thinner than liquid crystal cells, offer a tenfold greater resolution and consume 50% less energy.
As part of the study, the team demonstrated that pixels could be electrically-programmed and the light could be switched almost 20 times faster than human aversion response time by changing the temperature of the material.
According to the team their technology is compatible with modern electronic displays and fills a technological gap for tuneable metasurfaces capable of switching light effectively at high frequencies.
“We have paved the way to break a technology barrier by replacing the liquid crystal layer in current displays with a metasurface, enabling us to make affordable flat screens liquid crystal-free,” said the project leader Mohsen Rahmani, Professor of Engineering at Nottingham Trent University’s School of Science and Technology and a Royal Society Wolfson Fellow. “The most important metrics of flat panel displays are pixel size and resolution, weight and power consumption. We have addressed each of these with our meta-display concept.
“Most importantly, our new technology can lead to a huge reduction of energy consumption – this is excellent news given the number of monitors and TV sets being used in households and businesses every single day. We believe it is time for LCD and LED displays to be phased out in the same way as former cathode ray tube (CRT) TVs over the past ten to 20 years.”
Dragomir Neshev, Director of the ARC Centre for Excellence in Transformative Meta-Optical Systems (TMOS) and Australian National University Professor in Physics, said: “The capability of conventional displays has reached its peak and is unlikely to significantly improve in the future due to multiple limitations. Today there is a quest for fully solid-state flat display technology with a high-resolution and fast refresh rate. We have designed and developed metasurface pixels that can be ideal for the next-generation display. Unlike liquid crystals, our pixels do not require polarised lights for functioning, which will halve screens’ energy consumption.”
Commenting Dr Lei Xu, a team member from Nottingham Trent University, said, “There is significant room for further improvements by employing artificial intelligence and machine learning techniques to design and realise even smaller, thinner and more efficient metasurface displays.”
“Our pixels are made of silicon, which offers a long-life span in contrast with organic materials required for other existing alternatives. Moreover, silicon is widely available, CMOS compatible with mature technology, and cheap to produce,” added Professor Andrey Miroshnichenko, a team member from the University of New South Wales Canberra. He concluded that it was hoped the development could generate a frontier technology in new flat displays with a global market value of about $117 billion in 2020.
The work was first reported in the journal Light: Science & Applications.
