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Detectors and sensors

Detectors and sensors

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  * Detectors and sensors
  * Research update

Four-wave mixing could boost optical communications in space

09 Nov 2024
Optical receiver Four-wave mixing A weak optical signal (red) from a
spacecraft transmitter can be amplified noise-free when it encounters
two pump waves (blue and green) in a receiver on Earth. (Courtesy:
Chalmers University of Technology/Rasmus Larsson)

A new and practical approach to the low-noise amplification of
weakened optical signals has been unveiled by researchers in Sweden.
Drawing from the principles of four-wave mixing, Rasmus Larsson and
colleagues at Chalmers University of Technology believe their
approach could have promising implications for laser-based
communication systems in space.

Until recently, space-based communication systems have largely relied
on radio waves to transmit signals. Increasingly, however, these
systems are being replaced with optical laser beams. The shorter
wavelengths of these signals offer numerous advantages over radio
waves. These include higher data transmission rates; lower power
requirements; and lower risks of interception.

However, when transmitted across the vast distances of space, even a
tightly focused laser beam will spread out significantly by the time
its light reaches its destination. This will weaken severely the
signal's strength.

To deal with this loss, receivers must be extremely sensitive to
incoming signals. This involves the preamplification of the signal
above the level of electronic noise in the receiver. But conventional
optical amplifiers are far too noisy to achieve practical space-based
communications.

Phase-sensitive amplification

In a 2021 study, Larsson's team showed how these weak signals can, in
theory, be amplified with zero noise using a phase-sensitive optical
parametric amplifier (PSA). However, this approach did not solve the
problem entirely.

"The PSA should be the ideal preamplifier for optical receivers,"
Larsson explains. "However, we don't see them in practice due to
their complex implementation requirements, where several synchronized
optical waves of different frequencies are needed to facilitate the
amplification." These cumbersome requirements place significant
demands on both transmitter and receiver, which limits their use in
space-based communications.

To simplify preamplification, Larsson's team used four-wave mixing.
Here, the interaction between light at three different wavelengths
within a nonlinear medium produces light at a fourth wavelength.

In this case, a weakened transmitted signal is mixed with two strong
"pump" waves that are generated within the receiver. When the phases
of the signal and pump are synchronized inside a doped optical fibre,
light at the fourth wavelength interferes constructively with the
signal. This boosts the amplitude of the signal without sacrificing
low-noise performance.

Auxiliary waves

"This allows us to generate all required auxiliary waves in the
receiver, with the transmitter only having to generate the signal
wave," Larsson describes. "This is contrary to the case before where
most, if not all waves were generated in the transmitter. The
synchronization of the waves further uses the same specific lossless
approach we demonstrated in 2021."

The team says that this new approach offers a practical route to
noiseless amplification within an optical receiver. "After optimizing
the system, we were able to demonstrate the low-noise performance and
a receiver sensitivity of 0.9 photons per bit," Larsson explains.
This amount of light is the minimum needed to reliably decode each
bit of data and Larsson adds, "This is the lowest sensitivity
achieved to date for any coherent modulation format."

 
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This unprecedented sensitivity enabled the team to establish optical
communication links between a PSA-amplified receiver and a
conventional, single-wave transmitter. With a clear route to
noiseless preamplification through some further improvements, the
researchers are now hopeful that their approach could open up new
possibilities across a wide array of applications - especially for
laser-based communications in space.

"In this rapidly emerging topic, the PSA we have demonstrated can
facilitate much higher data rates than the bandwidth-limited single
photon detection technology currently considered."

This ability would make the team's PSA ideally suited for
communication links between space-based transmitters and ground-based
receivers. In turn, astronomers could finally break the notorious
"science return bottleneck". This would remove many current
restrictions on the speed and quantity of data that can be
transmitted by satellites, probes, and telescopes scattered across
the solar system.

The research is described in Optica.

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