# Bound states in the continuum: From fundamental physics to emerging photonic paradigms

**Authors:** Shubin Zhang, Ye Fan, Yufei Ma, Meixue Zong, Handong Sun, Zhiqiang Yang, Zhengji Xu

PMC · DOI: 10.1016/j.isci.2026.114803 · iScience · 2026-01-29

## TL;DR

This paper explores bound states in the continuum (BICs) in photonics, explaining their unique properties and potential for advanced optical technologies.

## Contribution

The paper provides a cohesive review of BICs, linking their theoretical foundations to practical photonic applications and future design possibilities.

## Key findings

- BICs enable high-Q resonances through symmetry, interference, or topology without fine parameter tuning.
- BICs allow for robust and controllable optical confinement and radiation in photonic structures.
- Quasi-BIC platforms demonstrate enhanced emission and non-local wavefront manipulation.

## Abstract

Bound states in the continuum (BICs) defy the conventional intuition of open photonic systems by supporting perfectly localized eigenmodes within the radiative spectrum. Originally conceived in quantum mechanics and later realized in photonics, BICs have evolved from a theoretical curiosity into a unifying framework for engineering high-Q resonances in periodic optical structures. Unlike conventional high-Q modes that rely on fine parameter tuning to suppress radiation, BICs arise from symmetry enforcement, destructive interference, or momentum-space topology, endowing them with intrinsic robustness and distinct design principles. This review provides a cohesive perspective on the physical origin, theoretical foundations, and emerging functionalities of BICs in photonic crystal slabs, metasurfaces, and related platforms. By bridging band theory, temporal coupled-mode theory, and multipole analysis with experimentally accessible observables, we elucidate how BIC physics enables rational control of confinement, radiation, and modal coherence. We further highlight recent advances in quasi-BIC platforms, demonstrating how controlled radiative coupling facilitates enhanced emission, nonlinear processes, and non-local wavefront manipulation. Looking forward, the integration of BIC concepts with topology-assisted design and reconfigurable photonic architectures points toward scalable, multifunctional, and intelligent photonic technologies.

Physics; Photonics; Applied sciences

## Full-text entities

- **Genes:** AIP (AHR interacting HSP90 co-chaperone) [NCBI Gene 9049] {aka ARA9, FKBP16, FKBP37, PITA1, SMTPHN, XAP-2}, MIR155HG (MIR155 host gene) [NCBI Gene 114614] {aka BIC, BIC-155, LncRNA-SERB, MIRHG2, NCRNA00172, miPEP155}
- **Chemicals:** metal (MESH:D008670), perovskite (MESH:C059910), GaSe (MESH:C517764), germanium (MESH:D005857), AlGaAs (-), silicon (MESH:D012825), graphene (MESH:D006108), silicon nitride (MESH:C032734), TiO2 (MESH:C009495), BIC (MESH:C100119), hydrogen (MESH:D006859)

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12915290/full.md

## References

158 references — full list in the complete paper: https://tomesphere.com/paper/PMC12915290/full.md

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Source: https://tomesphere.com/paper/PMC12915290