Physicists from ITMO University, Ioffe
Institute and Australian
National University
managed to make homogenous cylindrical objects completely invisible in the
microwave range.
Contrary to the now
prevailing notion of invisibility that relies on metamaterial coatings, the
scientists achieved the result using a homogenous object without any additional
coating layers. The method is
based on a new understanding of electromagnetic wave scattering. The results of
the study were published in Scientific Reports.
The scientists studied light scattering from a
glass cylinder filled with water. In essence, such an experiment represents a
two-dimensional analog of a classical problem of scattering from a homogeneous
sphere (Mie scattering), the solution to which is known for almost a century.
However, this classical problem contains unusual physics that manifests itself
when materials with high values of refractive index are involved. In the study,
the scientists used ordinary water whose refractive index can be regulated by
changing temperature.
As it turned out, high
refractive index is associated with two scattering mechanisms: resonant
scattering, which is related to the localization of light inside the cylinder,
and non-resonant, which is characterized by smooth dependence on the wave
frequency. The interaction between these mechanisms is referred to as Fano
resonances. The researchers discovered that at certain frequencies waves
scattered via resonant and non-resonant mechanisms have opposite phases and are
mutually destroyed, thus making the object invisible.
The work led to the
first experimental observation of an invisible homogeneous object by means of
scattering cancellation. Importantly, the developed technique made it possible
to switch from visibility to invisibility regimes at the same frequency of 1.9
GHz by simply changing the temperature of the water in the cylinder from 90 °C
to 50 °C.
“Our theoretical
calculations were successfully tested in microwave experiments. What matters is
that the invisibility idea we implemented in our work can be applied to other
electromagnetic wave ranges, including to the visible range. Materials with
corresponding refractive index are either long known or can be developed at
will,” said Mikhail Rybin, first author of the paper and senior researcher at
the Metamaterials Laboratory in ITMO
University .
The discovery of
invisibility phenomenon in a homogenous object and not an object covered with
additional coating layers is also important from the engineering point of view.
Because it is much easier to produce a homogeneous cylinder, the discovery
could prompt further development of nanoantennas, wherein invisible structural
elements could help reduce disturbances. For instance, invisible rods could be
used as supports for a miniature antenna complex connecting two optical chips.
The subject of
invisibility came into prominence with the development of metamaterials –
artificially designed structures with optical properties that are not
encountered elsewhere in nature. Metamaterials are capable of changing the
direction of light in exotic ways, including making light curve around the
cloaked object. Nevertheless, coating layers based on metamaterials are
extremely hard to fabricate and are not compatible with many other invisibility
ideas. The method developed by the group is based on a new understanding of
scattering processes and leaves behind the existing ones in simplicity and
cost-effectiveness.
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