# Phase‐Changing Vanadium Oxides for Electromagnetic Radiation Management

**Authors:** Mohammad Taha, Torben Daeneke, Sumeet Walia

PMC · DOI: 10.1002/smsc.202500614 · 2026-01-29

## TL;DR

Vanadium dioxide's unique phase transition enables ultrafast control of electromagnetic radiation, offering new possibilities for secure communications and smart materials.

## Contribution

The paper highlights vanadium dioxide's room-temperature, ultrafast, and durable phase transition for dynamic electromagnetic modulation.

## Key findings

- VO2 enables tuneable absorption rates from 2% to 100% with bandwidths up to 6.35 THz.
- VO2 metasurfaces provide polarisation insensitivity and multifunctional electromagnetic protection.
- VO2's cycling stability exceeds 100 million cycles with femtosecond response times.

## Abstract

Vanadium oxides and their polymorphs are transforming electromagnetic radiation security in communications and infrastructure. This arises from their broadband response and potential for wavelength attenuation across the ultraviolet, optical, infrared, and radio regions of the electromagnetic spectrum. More specifically, monoclinic vanadium dioxide's sharp, reversible insulator‐to‐metal transition near room temperature enables ultrafast, tuneable switching of conductivity and optical properties, triggered by thermal, optical, or electrical controls. Chalcogenide phase‐change materials require high crystallisation temperatures and nanosecond switching times, whereas VO2's volatile Mott transition operates near ambient conditions with femtosecond response and cycling stability exceeding 100 million cycles. This dynamic modulation supports real‐time absorption, shielding, and beam steering across terahertz, infrared, and radiofrequency domains, with demonstrated absorption rates tuneable from 2% to 100% and bandwidths up to 6.35 THz. VO2 metasurfaces offer polarisation insensitivity and multifunctionality, protecting against jamming, interception, and signal leakage. Advances in large‐area synthesis, nanostructuring, and durability have enabled both highly sensitive sensors and long‐lived smart coatings. These findings position vanadium oxides as transformative materials for physical‐layer electromagnetic security in wireless communications, infrastructure protection, and smart sensing systems.

Vanadium dioxide's reversible insulator‐to‐metal transition near room temperature enables ultrafast, broadband electromagnetic modulation from ultraviolet to radiofrequencies. With femtosecond switching speeds and cycling endurance exceeding 100 million cycles, VO2 metasurfaces achieve tuneable absorption, beam steering, and polarisation control. These volatile phase‐change properties position vanadium oxides as transformative platforms for physical‐layer electromagnetic security, adaptive shielding, and reconfigurable photonic systems.© 2026 WILEY‐VCH GmbH

## Linked entities

- **Chemicals:** vanadium dioxide (PubChem CID 82849), VO2 (PubChem CID 34008)

## Full-text entities

- **Chemicals:** Chalcogenide (-)

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12853973/full.md

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Source: https://tomesphere.com/paper/PMC12853973