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This chip is about the size of a fingernail and is made of thin film lithium niobate, for data communication (internet) or biological sensor, this chip is sensitive to environmental changes. Credit: RMIT University
Leading scientists in the field predict that ultra-thin lithium niobate chips will outperform silicon chips in light-based technologies. These chips have a wide range of potential applications, from remote identification of ripe fruit on Earth to navigation on the Moon.
According to the scientists, lithium niobate artificial crystal is the preferred platform for these technologies because of its superior performance and advances in manufacturing techniques.
RMIT University’s Distinguished Professor Arnan Mitchell and Adelaide University’s Dr Andy Boyce led this international panel of experts to review lithium niobate’s potential and applications in the journal Science.
The international team, including scientists from Peking University in China and Harvard University in the United States, is working with industry to develop navigation systems intended to help rovers drive on the moon later this decade.
This chip is about the size of a fingernail and is made of a thin film of lithium niobate. It can be used in various applications, including telecommunications, to make the Internet faster. Credit: RMIT University
Since it is not possible to use the Global Positioning System ([{” attribute=””>GPS) technology on the Moon, navigation systems in lunar rovers will need to use an alternative system, which is where the team’s innovation comes in.
By detecting tiny changes in laser light, the lithium-niobate chip can be used to measure movement without needing external signals, according to Mitchell.
“This is not science fiction – this artificial crystal is being used to develop a range of exciting applications. And the competition to harness the potential of this versatile technology is heating up,” said Mitchell, Director of the Integrated Photonics and Applications Centre.
He said while the lunar navigation device was in the early stages of development, the lithium niobate chip technology was “mature enough to be used in space applications”.
“Our lithium niobate chip technology is also flexible enough to be rapidly adapted to almost any application that uses light,” Mitchell said.
“We are focused on navigation now, but the same technology could also be used for linking the internet on the Moon to the internet on Earth.”
What is lithium niobate and how can it be used?
Lithium niobate is an artificial crystal that was first discovered in 1949 but is “back in vogue”, according to Boes.
“Lithium niobate has new uses in the field of photonics – the science and technology of light – because unlike other materials it can generate and manipulate electromagnetic waves across the full spectrum of light, from microwave to UV frequencies,” he said.
“Silicon was the material of choice for electronic circuits, but its limitations have become increasingly apparent in photonics.
“Lithium niobate has come back into vogue because of its superior capabilities, and advances in manufacturing mean that it is now readily available as thin films on semiconductor wafers.”
A layer of lithium niobate about 1,000 times thinner than a human hair is placed on a semiconductor wafer, Boes said.
“Photonic circuits are printed into the lithium niobate layer, which are tailored according to the chip’s intended use. A fingernail-sized chip may contain hundreds of different circuits,” he said.
How does the lunar navigation tech work?
The team is working with the Australian company Advanced Navigation to create optical gyroscopes, where laser light is launched in both clockwise and anticlockwise directions in a coil of fiber, Mitchell said.
“As the coil is moved the fiber is slightly shorter in one direction than the other, according to Albert Einstein’s theory of relativity,” he said.
“Our photonic chips are sensitive enough to measure this tiny difference and use it to determine how the coil is moving. If you can keep track of your movements, then you know where you are relative to where you started. This is called inertial navigation.”
Potential applications closer to home
This technology can also be used to remotely detect the ripeness of fruit.
“Gas emitted by ripe fruit is absorbed by light in the mid-infrared part of the spectrum,” Mitchell said.
“A drone hovering in an orchard would transmit light to another which would sense the degree to which the light is absorbed and when fruit is ready for harvesting.
“Our microchip technology is much smaller, cheaper, and more accurate than current technology and can be used with very small drones that won’t damage fruit trees.”
Next steps
Australia could become a global hub for manufacturing integrated photonic chips from lithium niobate that would have a major impact on applications in technology that use every part of the spectrum of light, Mitchell said.
“We have the technology to manufacture these chips in Australia and we have the industries that will use them,” he said.
“Photonic chips can now transform industries well beyond optical fiber communications.”
Reference: “Lithium niobate photonics: Unlocking the electromagnetic spectrum” by Andreas Boes, Lin Chang, Carsten Langrock, Mengjie Yu, Mian Zhang, Qiang Lin, Marko Lončar, Martin Fejer, John Bowers and Arnan Mitchell, 6 January 2023, Science.
DOI: 10.1126/science.abj4396
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