N-tupling the capacity of each polarization state in radio links by using electromagnetic vorticity

The congestion of the radio frequency bands imposes serious limitations on the capacity and capability of modern wireless information infrastructures. One approach to enable frequency re-use is to exploit other physical conserved quantities of the electromagnetic fields, such as the orbital angular momentum (OAM) in addition to linear momentum, which is exploited in present-day telecommunications. Whereas in the optical regime the increase of channel capacity by using OAM states was demonstrated recently, the receiving antennas in commercial radio links have a much smaller extent than the transmitted beam, making the signal reception and characterization of the OAM state demanding. Moreover, radio data transmission with more than two channels per polarization state at the same frequency for radio links is known to be notoriously difficult to realize even with multiport techniques, long antenna baselines and digital post-processing. Here we report results from an outdoor, proof of concept experiment where the physical properties of OAM states were used to transfer information, using far-field multiplexing/demultiplexing of three coexisting collinear, vertically polarized and mutually independent OAM radio beams, opening new perspectives in wireless telecommunications.