New Device Switches Terahertz Pulses Between Electric and Magnetic Skyrmions

Terahertz frequencies are emerging as a cornerstone for next‑generation wireless links, offering bandwidths far beyond conventional microwave bands. Within this spectrum, structured light such as skyrmions—topologically protected vortex rings—adds a hidden layer of information that can survive noise and scattering. By embedding electric and magnetic skyrmion states into a single terahertz pulse, researchers unlock a dual‑mode channel that effectively doubles the encoding space without expanding the physical spectrum.

The core of the new device is a nonlinear metasurface composed of intricately patterned metallic nanostructures. When shaped near‑infrared femtosecond pulses strike the surface, the metasurface’s nonlinear response converts them into terahertz toroidal pulses carrying either an electric‑mode or magnetic‑mode vortex, depending on the input polarization. Simple optical components—wave plates and vortex retarders—act as switches, allowing on‑demand selection of the desired topological state. Laboratory measurements confirm that each mode retains high purity and can be toggled with sub‑nanosecond latency, meeting the speed requirements of modern data links.

From a commercial perspective, this technology promises more resilient terahertz communication systems, where data streams can be dynamically re‑routed by changing skyrmion states rather than relying on traditional amplitude or phase modulation. The compact, integrated nature of the metasurface also aligns with the industry’s push toward miniaturized photonic circuits, potentially enabling on‑chip terahertz routers and processors. As standards for 6G and beyond evolve, switchable skyrmion devices could become a key enabler for ultra‑high‑capacity, interference‑tolerant networks.