# Dynamic tuning of Bloch modes in anisotropic phonon polaritonic crystals

**Authors:** Junbo Xu, Ke Yu, Xiang Ni, Enrico M. Renzi, Lei Zhou, Yanzhen Yin, Zhou Zhou, Zhichen Zhao, Tao He, Di Huang, Kyoung-Duck Park, Zhanshan Wang, Andrea Alù, Tao Jiang

PMC · DOI: 10.1038/s41377-025-02157-6 · 2026-01-03

## TL;DR

Researchers developed a way to dynamically control light at the nanoscale using a graphene-gated crystal, enabling adaptive nanophotonics.

## Contribution

The study introduces electrostatic tuning of anisotropic phonon-polaritonic Bloch modes for dynamic nanoscale light manipulation.

## Key findings

- Electrostatic gating reshapes the band structure of phonon polaritonic crystals.
- Dynamic modulation enables selective amplification of Bloch mode resonances.
- On-demand switching of far-field leakage is achieved through band steering.

## Abstract

Phonon polaritons, arising from the coupling of photons with lattice vibrations, enable light confinement on deeply subwavelength scales. Phonon polaritonic crystals (PoCs), leveraging these inherently low-dissipation excitations, have further shown exceptional potential for nanoscale light manipulation through engineered Bloch modes. Yet, their static nature has so far hindered dynamic modulation, thus limiting their adaptability for real-time applications. Here, we demonstrate in situ electrostatic control of low-loss anisotropic phonon-polaritonic Bloch modes in α-MoO3 patterned into a periodic hole array with a graphene gate. Through theoretical calculation and real-space nano-imaging, we show that electrostatic gating dynamically modulates key characteristics of Bloch modes in hybrid α-MoO3/graphene PoCs. Critically, gating reshapes the PoC band structure, spectrally aligning high-density-of-states flat-band regions with the excitation laser frequency, thereby selectively amplifying Bloch mode resonances. We further achieve on-demand switching over far-field leakage of Bloch modes by electrostatically steering these flat bands across the light cone. Our work establishes a platform for adaptive nanostructured phonon polaritonic devices. This advancement not only facilitates directional control of low-loss anisotropic phonon-polaritonic Bloch modes, but also paves the way for their practical application in nanophotonics.

This work demonstrates actively controlled, low-loss phonon-polaritonic Bloch modes in a graphene-gated α-MoO3 polaritonic crystal, which enables enhanced near-field resonances and switchable far-field leakage through band structure modulation.

## Full-text entities

- **Chemicals:** graphene (MESH:D006108), alpha-MoO3 (-)

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12764765/full.md

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Source: https://tomesphere.com/paper/PMC12764765