WHY THIS MATTERS IN BRIEF
Light is amazing, and it’s also incredibly powerful and useful as a tool, and we’re using it to innovate all manner of new technologies and applications.
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Scientists have a fixation with light – whether it’s turning it into a liquid, bringing it to a standstill, turning it into sound, or just plain using it to create the first generation of ultra-fast photonic computers and neural networks, or cameras that can see around corners and take pictures through walls. Now though they’ve found a way to make solid objects “invisible” in a strange way – by having light waves pass through opaque materials as if they were not there at all. The breakthrough also adds yet another way to turn objects invisible after researchers in Canada used metamaterials to create the first invisibility cloaks …
The reason that objects are visible are because of the scattering of light waves, bouncing from a light source onto an item and then into the human eye.
However, research from TU Wien and Utrecht University have been able to calculate a specific variety of light wave that could penetrate an object. While one might think that all light waves are the same, this is not the case.
Objects are no obstacle for this lightwave …
“Each of these light wave patterns is changed and deflected in a very specific way when you send it through a disordered medium,” explained Professor Stefan Rotter from the Institute of Theoretical Physics at TU Wien in a statement.
The execution of this is very challenging, and precise. In an experiment Professor Rotter and Professor Allard Mosk, at Utrecht University, used a layer of opaque zinc oxide powder – randomly arranged nanoparticles – and calculated exactly how light is scattered by the powder, and how it would have been scattered if the powder was not there at all.
With this knowledge the researchers found that a certain type of light wave, called scattering-invariant light modes, was recorded by a detector on the other side of the powder in exactly the same pattern – albeit slightly weaker than when they were sent.
Moreover, there are a theoretically unlimited number of light waves; this means that while they are difficult to calculate, they can be found. This new development could prove significantly beneficial to imaging procedures in biomedical applications.
“One aspect we are very excited about is the fact that the light fields we introduced in our work not only seem to be special in the output field patterns they produce behind the object, but also inside of it,” said Professor Rotter, which when combined with new Terahertz cameras and 3D printers could, for example, let you image an entire object, inside and out, digitise it, and then print it out, or clone it, on demand.
“The feature that these fields resemble those in free space could be very useful for looking deep inside highly scattering materials that are typically very challenging to work with.”
There is still research to be done, Professor Rotter added, as biological systems are full of movement, such as blood flowing through the body. This makes it hard to calculate the patterns needed to have light pass through the object, as the measurements need to be done more rapidly than the timescale of the movement itself, but it’s likely that Artificial Intelligence (AI) could help solve some of that problem …
For now the breakthrough could help scientists that want to examine smaller structures, such as cells, and Professor Rotter believes that it is only a matter of time before the measurement tools become fast enough and cheaper enough to open the possibilities of more sophisticated applications.
The results have now been published in the journal Nature Photonics.
