| Jan 29, 2026 |
Researchers propose a method to detect and map low-frequency excitations in nonlinear materials at nanometer resolution, enabling far-infrared fingerprints.
(Nanowerk News) Atoms never remain perfectly fixed, even inside solid materials. Instead, they vibrate around their equilibrium positions, giving rise to collective excitations known as phonons. These and other fundamental excitations are extremely hard to measure with nanoscale spatial resolution, mainly because their frequencies are too low for conventional optical techniques to resolve. Indeed, a method capable of accessing information in the far-infrared to terahertz regime with nanometer resolution does not yet exist.
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Now, ICFO researchers, Leila Prelat and Dr. Eduardo Dias, led by ICREA Prof. F. Javier García de Abajo, have theoretically proposed a new technique called wave-mixing cathodoluminescence (WMCL) to map low-frequency (far-infrared to terahertz) excitations in nonlinear materials with nanometer resolution. The approach, reported in Nature Communications (“Wave-mixing cathodoluminescence microscopy of low-frequency excitations”), relies exclusively on visible light, eliminating the need for specialized low-frequency light sources and detectors.
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The WMCL method begins by directing an electron beam onto the sample, where it gives rise to low-frequency excitations, such as phonon vibrations. At the same time, the specimen is illuminated with visible laser light. Because of the material’s nonlinear optical response, the laser light and the low-frequency excitations interact rather than evolving independently, becoming mixed through a wave-mixing process. This interaction produces a tiny but detectable frequency shift in the scattered laser light, which nevertheless remains in the visible range.
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In this way, the small frequency offset encodes the terahertz information, even though the detected light is still visible. “In other words, nonlinear mixing allows invisible low-frequency excitations to imprint themselves onto visible photons,” explains Leila Prelat, first author of the article. Prof. Javier García de Abajo, lead researcher of the study, adds: “This method opens a new low-frequency measurement channel in a field where no existing techniques can meet the required combination of spatial and spectral resolution.”
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The team has also shown how WMCL could be used to identify different chemical components within thin molecular layers deposited on nanostructures. In particular, they analyzed silver nanorods (elongated one-dimensional nanostructures) coated with a molecular layer of retinal. An experimental realization is now needed to validate these predictions and explore additional applications, including extending WMCL beyond molecular vibrations to probe other types of low-frequency excitations.
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