Researchers at the University of Illinois at Urbana-Champaign have replicated one of the most well-known electromagnetic effects in physics, the Hall effect, using radio waves (photons) instead of electric current (electrons). Their technique could be used to create advanced communication systems that boost signal transmission in one direction while simultaneously absorbing signals going in the opposite direction.
The Hall effect, discovered in 1879 by Edwin Hall, occurs because of the interaction between charged particles and electromagnetic fields. In an electric field, negatively charged particles (electrons) experience a force opposite to the direction of the field. In a magnetic field, moving electrons experience a force in the direction perpendicular to both their motion and the magnetic field.
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These two forces combine in the Hall effect, where perpendicular electric and magnetic fields combine to generate an electric current. Light isn’t charged, so regular electric and magnetic fields can’t be used to generate an analogous “current of light.” However, in a recent paper published in Physical Review Letters, researchers have done exactly this with the help of what they call “synthetic electric and magnetic fields.”
Principal investigator Gaurav Bahl’s research group has been working on several methods to improve radio and optical data transmission as well as fiber optic communication. Earlier this year, the group exploited an interaction between light and sound waves to suppress the scattering of light from material defects and published its results in Optica.
In 2018, team member Christopher Peterson was the lead author in a Science Advances paper that explained a technology that promises to halve the bandwidth needed for communications by allowing an antenna to send and receive signals on the same frequency simultaneously through a process called nonreciprocal coupling.
In the current study, Peterson has provided another promising method to directionally control data transmission using a principle similar to the Hall effect. Instead of an electric current, the team generated a “current of light” by creating synthetic electric and magnetic fields, which affect light the same way the normal fields affect electrons.
Unlike conventional electric and magnetic fields, these synthetic fields are created by varying the structure that light propagates through in both space and time. Peterson explained:
“Although radio waves do not carry charge and therefore do not experience forces from electric or magnetic fields, physicists have known for several years that equivalent forces can be produced by confining light in structures that vary in space or time.
“The rate of change of the structure in time is effectively proportional to the electric field, and the rate of change in space is proportional to the magnetic field. While these synthetic fields were previously considered separately, we showed that their combination affects photons in the same way that it affects electrons.”
By creating a specially designed circuit to enhance the interaction between these synthetic fields and radio waves, the team leveraged the principle of the Hall effect to boost radio signals going in one direction, increasing their strength, while also stopping and absorbing signals going in the other direction.
Their experiments showed that with the right combination of synthetic fields, signals can be transmitted through the circuit more than 1000-times as effectively in one direction than in the opposite direction.
Their research could be used to produce new devices that protect sources of radio waves from potentially harmful interference, or that help ensure sensitive quantum mechanical measurements are accurate. The team is also working on experiments that extend the concept to other kinds of waves, including light and mechanical vibrations, as they look to establish a new class of devices based on applying the Hall effect outside of its original domain.
In addition to Peterson and Bahl, co-authors Prof. Taylor Hughes, Mao Lin (Department of Physics at Illinois), and Dr. Wladimir Benalcazar (Physics at Penn State University) contributed to the theoretical developments in this work.
Provided by: University of Illinois at Urbana-Champaign [Note: Materials may be edited for content and length.]