EPFL, Lausanne, Switzerland, has collaborated with Harvard and ETH Zurich on a new thin-film circuit that, when connected to a laser beam, produces finely-adjustable terahertz-frequency waves. The partners say the device “opens up a world of potential applications in optics and telecommunications”.
The researchers led by Cristina Benea-Chelmus in the Laboratory of Hybrid Photonics (HYLAB) in EPFL’s School of Engineering have “taken a big step toward successfully exploiting the so-called terahertz gap”, which lies between about 0.3 to 30 THz. This range is currently “something of a technological dead zone”, said EPFL, comprising frequencies that are too fast for electronics and telecommunications devices, but too slow for optics and imaging applications.
Now, thanks to an extremely thin chip with an integrated photonic circuit made of lithium niobate, the HYLAB researchers and colleagues at ETH Zurich and Harvard University have succeeded not just in producing terahertz waves, but in engineering a solution for custom-tailoring their frequency, wavelength, amplitude, and phase.
Such precise control over terahertz radiation means that it can now potentially be harnessed for next-generation applications in both the electronic and optical realms. The results are published in Nature Communications.
“Seeing the devices emit radiation with properties that we predefined was a confirmation that our model was correct,“ said co-first author Alexa Herter, currently a PhD student at ETH Zurich.
“This was made possible due to the unique features of lithium niobate integrated photonics,” said co-first author Amirhassan Shams-Ansari, a postdoctoral fellow at Harvard University.
Benea-Chelmus explained that while such terahertz waves have been produced in a lab setting before, previous approaches have relied primarily on bulk crystals to generate the right frequencies. Her lab’s use of the lithium niobate circuit, finely etched at the nanometer scale by collaborators at Harvard University, makes their novel approach much more streamlined. A silicon substrate also makes the device suitable for integration into electronic and optical systems.
“Generating waves at very high frequencies is extremely challenging, and there are very few techniques that can generate them with unique patterns. We are now able to engineer the exact temporal shape of terahertz waves – to say essentially, ‘I want a waveform that looks like this,’” she said.
To achieve this, Benea-Chelmus’ lab designed the chip’s arrangement of channels called waveguides, from which microscopic antennas broadcast terahertz waves generated by light from optical fibers.
“The fact that our device already makes use of a standard optical signal is really an advantage, because it means that these new chips can be used with traditional lasers, which work very well and are very well understood. It means our device is telecommunications-compatible,” Benea-Chelmus said.
Benea-Chelmus sees particular potential for miniaturized lithium niobate chips in spectroscopy and imaging. In addition to being non-ionizing, terahertz waves are much lower-energy than many other types of waves (like X-rays) currently used to provide information about the composition of a material. A compact, non-destructive device like the lithium niobate chip could therefore provide a less invasive alternative to current spectrographic techniques.
Next, Benea-Chelmus plans to focus on tweaking the properties of the chip’s waveguides and antennas to engineer waveforms with greater amplitudes, and more finely tuned frequencies and decay rates. She also sees potential for the terahertz technology developed in her lab to be useful for quantum applications.