Nature Communications (Aug 2024)

Nonlocal meta-lens with Huygens’ bound states in the continuum

  • Jin Yao,
  • Fangxing Lai,
  • Yubin Fan,
  • Yuhan Wang,
  • Shih-Hsiu Huang,
  • Borui Leng,
  • Yao Liang,
  • Rong Lin,
  • Shufan Chen,
  • Mu Ku Chen,
  • Pin Chieh Wu,
  • Shumin Xiao,
  • Din Ping Tsai

DOI
https://doi.org/10.1038/s41467-024-50965-y
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 8

Abstract

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Abstract Meta-lenses composed of artificial meta-atoms have stimulated substantial interest due to their compact and flexible wavefront shaping capabilities, outperforming bulk optical devices. The operating bandwidth is a critical factor determining the meta-lens’ performance across various wavelengths. Meta-lenses that operate in a narrowband manner relying on nonlocal effects can effectively reduce disturbance and crosstalk from non-resonant wavelengths, making them well-suitable for specialized applications such as nonlinear generation and augmented reality/virtual reality display. However, nonlocal meta-lenses require striking a balance between local phase manipulation and nonlocal resonance excitation, which involves trade-offs among factors like quality-factor, efficiency, manipulation dimensions, and footprint. In this work, we experimentally demonstrate the nonlocal meta-lens featuring Huygens’ bound states in the continuum (BICs) and its near-infrared imaging application. All-dielectric integrated-resonant unit is particularly optimized to efficiently induce both the quasi-BIC and generalized Kerker effect, while ensuring the rotation-angle robustness for generating geometric phase. The experimental results show that the single-layer nonlocal Huygens’ meta-lens possesses a high quality-factor of 104 and achieves a transmission polarization conversion efficiency of 55%, exceeding the theoretical limit of 25%. The wavelength-selective two-dimensional focusing and imaging are demonstrated as well. This work will pave the way for efficient nonlocal wavefront shaping and meta-devices.