A thermoradiative diode which is able to
transmit hidden data. Credit: UNSW
Engineers at UNSW Sydney and Monash
have developed an innovative way of sending hidden information that's hard to
intercept. Using a phenomenon known as "negative luminescence," the
system works by making signals blend perfectly into the background of natural
heat radiation, such as can be seen with a thermal camera.
To outside observers, it looks like
no data is being sent at all. Only a receiver with the right equipment can pick
up the hidden message.
Because the very act of
communication is invisible, the method makes signals almost impossible to
intercept or hack. That means it could one day offer a powerful new security
tool for sensitive communications in fields like defense and finance.
The research team, led by UNSW
Professor Ned Ekins-Daukes and Dr. Michael Nielsen, including Professors
Michael Fuhrer and Stefan Maier from Monash University and Imperial College
London, have so far managed to send data at about 100 kilobytes per second in
lab experiments.
But they
believe speeds could reach gigabytes or even faster with further improvements
to the emitter technology.
"Data is
so ubiquitous nowadays, but we're not necessarily coming up with new ways to
protect that data," said Dr. Michael Nielsen, lead author from UNSW's
School of Photovoltaic and Renewable Energy Engineering.
"We do
have encryption methods, but at the same time, we're always having to create
new encryption methodologies when bad actors find new decryption strategies.
"But if
someone doesn't even know the data is being transferred, then it's really very
hard for them to hack into it. If you can send information secretly, then it
definitely helps to prevent it being acquired by people you don't want to
access it."
The new
process, described in a paper published in Light Science
and Applications, utilizes the special effect of negative
luminescence from LEDs operating in the mid-infrared part of the light
spectrum.
Everything
gives off a faint glow of heat in the infrared, which we normally can't
see—unless using special thermal cameras.
"What
makes negative luminescence so interesting is that it makes that glow look
darker instead of brighter. By way of a comparison, it would be like a
flashlight that can somehow go darker than 'off,'" added Dr. Nielsen.
"While
that's not possible to achieve with visible light, certain materials can create
this 'negative light' effect in infrared, which is what the research team are
now exploiting.
"In
traditional data communication, information is transferred by something being
either on or off. That can be as basic as a flashing light, or radio waves, or
signals sent down optical fibers.
"Observers
are able to see that data is being transmitted, even if they cannot read the
message because of it being encrypted in some way.
"But with
negative luminescence it is possible to create a hidden signal using a special
device called a thermoradiative diode."
The diode can
switch output quickly between brighter and darker-than-usual states, which
creates a pattern that blends into the usual background "noise" and
is therefore invisible to anyone not aware that data is being sent.
The hidden
information transmitted by such thermoradiative diodes can also be encrypted in
traditional ways, adding yet another level of security.
Future directions of thermoradiative
signatureless communication. Credit: Light: Science &
Applications (2026). DOI: 10.1038/s41377-025-02119-y
Thermoradiative diodes
The use of thermoradiative diodes in such a way was inspired by Prof. Ekins-Daukes
and his UNSW colleagues' previous innovative work in producing so-called "night-time solar"—electricity created from solar power even when
the sun has set.
"We technically call this new
process thermoradiative signatureless communication. As part of our work on the
night-time solar project, we determined that the negative luminescent property
was critical to how good our thermoradiative diodes performed," said Prof.
Ekins-Daukes.
"Today we have demonstrated a
thermoradiative surface that can be modulated such that the signal is
transmitted in all directions. Future iterations of the technology can make it
directional and, in the longer-term, guided in a way similar to fiber communications."
The team are confident the data
transfer speeds will increase dramatically over the proof-of-concept device
reported.
"A commercial product
delivering megabit data rates can be envisioned within a few years of
development. Here in Sydney we have the semiconductor equipment we need to
produce the next-generation prototypes of this device at the Australian
National Fabrication Facility on the UNSW campus," said Prof.
Ekins-Daukes.
"For this research we have
been working with mercury cadmium telluride, but we are actively exploring less
toxic antimonide-based semiconductors.
"Our colleagues at Monash University have already proposed that if we could use graphene—which is a very conductive material made up of a single layer of carbon atoms arranged like a honeycomb—then we can potentially achieve data transfer rates in the gigabytes per second range, if not hundreds of gigabytes."
Provided by University of New South Wales
Source: New 'negative light' technology hides data transfers in plain sight
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