The technique relies on manipulating what is known as the orbital angular momentum of the waves.
Recent work suggests that the trick could vastly boost the data-carrying capacity in wi-fi and optical fibres.
The striking demonstration of the approach, reported in Nature Photonics, is likely to lead to even higher rates.
Angular momentum is a slippery concept when applied to light, but an analogy closer to home is the Earth itself.
Our planet has "spin angular momentum" because it spins on its axis, and "orbital angular momentum" because it is also revolving around the Sun.
Light can have both these types, but the spin version is the far more familiar – as what is commonly called polarisation, or the direction along which light waves wiggle. Polarising sunglasses and many 3D glasses work by passing one polarisation and not another.
In many data-carrying applications involving light, more data is packed on to light waves by encoding one polarisation with one data stream, and another with a different stream.
That means twice as much information can fit within the same "bandwidth" – the range of colours that the transmitting equipment is able to process.
Twisted mission
Orbital angular momentum, or OAM, on the other hand, has only recently come to the fore as a promising means to accomplish the same trick.
The idea is not to create light waves wiggling in different directions but rather with different amounts of twist, like screws with different numbers of threads.
Most recently, Bo Thide of the Swedish Institute of Space Physics and a team of colleagues in Italy demonstrated the principle by sending beams made up of two different OAM states across a canal in Venice, an experiment they described in the New Journal of Physics.