(Nanowerk News) For years, scientists have dismissed terahertz radiation. Why? There were few ways to control this line-of-sight, nonionizing radiation. However, they saw its potential. |
For example, it could be used for short-range, high-bandwidth communications for tiny medical and environmental sensors. |
Now, researchers have developed a way to magnetically control terahertz beams using specially designed nanoparticles. By controlling the strength and direction of the applied magnetic field, the nanoparticles dynamically tuned a terahertz beam’s phase and amplitude (Nanoscale, "Magnetoelastoelectric coupling in core–shell nanoparticles enabling directional and mode-selective magnetic control of THz beam propagation").
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Engineered nanoparticle modulates terahertz radiation. The image shows the different magnetic and electric effects that occur in the cobalt ferrite (CFO) core (square) and surrounding barium titanate (BTO) shell (sphere) when an assembly of nanoparticles is operated in an external magnetic field (B). The direction of the applied magnetic field with respect to the terahertz beam leads to amplitude (antiparallel B) and phase (parallel B) modulation of a transmitted terahertz pulse via the magneto-elasto-electric (MEE) effect. The applied magnetic field produces a surface polarization charge density ssb on the nanoparticle shell. (© Royal Society of Chemistry) |
This study shows the potential for engineered nanoparticles to magnetically control terahertz beams. Controlling the amplitude and phase of the beams at the nanoscale offers a range of possibilities. |
For example, the nanoparticles could enable tiny, high frequency transistors. The particles could also help create wireless networks that let nanorobots work together. |
The terahertz spectral window (100 gigahertz to 10 terahertz) is attracting attention for its potential use in submillimeter-wave communication and sensing systems. While there is still much to be learned about this spectral band, nanostructures will likely play a significant role in the development of future terahertz systems for real-world applications. |
Using advanced electronic materials that simultaneously possess both magnetism and ferroelectricity, researchers from the University of Texas at San Antonio and the Center for Integrated Nanotechnologies demonstrated magnetic control of a terahertz beam. |
The team used a hydrothermal method to synthesize nanoparticles composed of a ferromagnetic core (cobalt ferrite) and a ferroelectric shell (barium titanate). Assemblies of these nanoparticles were then operated under the influence of an external magnetic field and at a low temperature. |
The team varied whether they applied the magnetic field parallel or antiparallel to the direction of a terahertz beam. They observed different effects for the two magnetic field orientations. When applied antiparallel to the terahertz beam, the nanoparticle assembly modulated the amplitude of the transmitted terahertz beam. When applied parallel, the nanoparticle assembly modulated the phase of the terahertz beam. |
These effects are due to the different types of magnetic and electric coupling that occurs between the ferromagnetic core and ferroelectric shell of the nanoparticles. |
This research uncovers an exciting new approach for the dynamic control of terahertz wave propagation by way of nanoparticles. It demonstrates a terahertz mode-switch where the mode of modulation–amplitude or phase–can be dynamically switched by changing the direction of the applied external magnetic field. |
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