Media release
Faculty of Science
The University of Auckland
8 July 2013
Studying waves over astronomical distances
Tiny pulses of light one billionth of a second apart, travelling further than from the Earth to Sun, were used in an
exquisitely sensitive experiment at The University of Auckland to explore fundamental interactions between light and
sound.
The research, led by Associate Professor Stéphane Coen from the Department of Physics, examined the behaviour of
solitons.
Solitons are solitary waves which maintain their shape in contrast, for instance, to waves hitting the shore which break
and fragment. They are found in a wide range of situations, and learning more about them will help physicists understand
many phenomena in the natural world.
Solitons were first seen in shipping canals, in which a boat coming to a sudden stop gave rise to a single large
propagating wave. They also describe tsunamis – waves which travel unabated across entire oceans – and appear in both
scorching hot nuclear fusion plasmas and ultracold gases.
In addition, solitons exist in microscopic glass rings, new devices used by scientists to generate frequency combs.
These are a type of light source used to make extremely accurate measurements and which underpinned a Nobel Prize in
2005.
The University of Auckland work examined how two solitons in the same system affect one another. It reports the weakest
interaction ever measured between solitons, and has been published in the prestigious journal Nature Photonics.
“This was beautifully sensitive work, and tests our understanding of the fundamental properties of nature,” says Head of
Department of Physics Professor Richard Easther.
The experiment was done using a loop of fibre optic cable. Two pulses (solitons) of laser light were fired into the loop
one billionth of a second apart, and allowed to continue travelling until one was found to have an influence on the
other.
It wasn’t until the pulses had travelled 150 million kilometres – the distance from the Earth to the Sun – that an
effect was observed. The gap separating the pulses changed by a billionth of a billionth of a second for every roundtrip
in the 100 metre-long loop.
As it travelled, the first pulse created an ultrasound wave in the fibre that disturbed the path of the second, detected
as a change in its velocity. The effect was so tiny that it could only be observed after the pulses had travelled
astronomical distances.
This was the first time an experimental apparatus had been built that allowed such weak interactions to occur and to be
observed.
The work was done by University of Auckland physicists Associate Professor Stéphane Coen, Dr Stuart Murdoch, Dr Miro
Erkintalo, and PhD student Jae Jang. It was supported by a Marsden grant of The Royal Society of New Zealand awarded to
Associate Professor Coen and colleagues in 2011.
These researchers are now looking to extend this work, and take advantage of their new understanding to facilitate the
use of solitons in communications applications.
Notes
This research, titled “Ultra-weak long-range interactions of solitons observed over astronomical distances” will be
published online ahead of print on the Nature Photonics website.
ENDS