Mid-infrared chiral planar metasurface thermal emitters based on quasiguided modes
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Summary
This study presents a novel planar metasurface for efficient mid-infrared chiral thermal emission. The design achieves narrowband, high circular dichroism (CD) emission, crucial for advanced spectroscopy and sensing applications.
Area of Science:
- Optics and Photonics
- Materials Science
- Spectroscopy
Background:
- Infrared circularly polarized emission is vital for vibrational circular dichroism (CD) spectroscopy.
- Fabricating 3D chiral structures for such applications presents significant challenges.
Purpose of the Study:
- To design a planar chiral all-dielectric metasurface for narrowband, high CD chiral thermal emission in the mid-infrared (MIR) region.
- To overcome fabrication limitations of traditional 3D chiral structures.
Main Methods:
- Utilized quasiguided modes and in-plane displacement perturbations.
- Employed Brillouin zone folding and symmetry breaking for chiral emission.
- Applied theoretical analysis, temporal coupled-mode theory, and Jones matrix for reflection characteristics.
- Performed multipole expansion analysis to identify dominant resonances.
Main Results:
- Achieved narrowband, high CD chiral thermal emission sources.
- Demonstrated selective emission of right-handed circularly polarized light with CD values close to ±1.
- Verified robustness against structural parameter and incident angle variations through simulations.
Conclusions:
- The planar metasurface design offers a viable solution for MIR chiral sensing and efficient thermal emission.
- The proposed structure exhibits high Q factors, narrow bandwidths, and planar fabrication compatibility.
- This work provides significant potential for applications in advanced optical sensing and emission technologies.