Researchers have added a new twist to create photon pairs that fit on a tiny computer chip. The breakthrough heralds the next-generation of integrated quantum optical technology, being compatible with current technology and secure communications.
The research team pioneered a new approach based on a micro-ring resonator — a tiny optical cavity — in which energy conservation constraints can be exploited to suppress classical effects while amplifying quantum processes.
The team, co-led by RMIT MicroNano Research Facility Director Professor David Moss, used laser beams at different wavelengths and then had to overcome the risk of the two pump beams being able to destroy the photons’ fragile quantum state.
“One of the properties of light exploited within quantum optics is ‘photon polarization,’ which is essentially the direction in which the electric field associated with the photon oscillates,’’ Moss said.
“Processes used to generate single photons or photon pairs on a chip allow the generation of photons with the same polarization as the laser beam, forcing us to find a way to directly mix, or cross-polarize, the photons via a nonlinear optical process on a chip for the first time.’’
Moss worked with Professor Roberto Morandotti at the INRS-EMT in Canada and researchers from the University of Sussex and Herriot Watt University, City University of Hong Kong, and the Xi’an Institute in Chin, on the research.
“While a similar suppression of classical effects has been observed in gas vapors and complex micro-structured fibers, this is the first time it has been reported on a chip, opening a route for building scalable integrated devices that exploit the mixing of polarization on a single photon level,’’ he said.
“It also has the advantage that the fabrication process of the chip is compatible with that currently used for electronic chips, which not only allows the exploitation of the huge global infrastructure of CMOS foundries, but will ultimately offer the potential to integrate electronic devices on the same chip.
“Both of these are fundamental requirements for the ultimate widespread adoption of optical quantum technologies.’’
The research was published in Nature Communications.