In a groundbreaking advancement at the intersection of non-Hermitian physics and photonic metamaterials, researchers from Nanjing University have demonstrated the first observation of the transition from a single bound state in the continuum (BIC) singularity to a two-dimensional exceptional ring. This milestone represents a significant leap in understanding topological singularities within non-Hermitian systems and paves the way for novel applications across terahertz (THz) technology and integrated optics.
Bound states in the continuum (BICs) originated as purely quantum mechanical phenomena characterized by modes that remain localized despite existing within a continuous spectrum of radiative modes. Exceptional points (EPs), on the other hand, are non-Hermitian spectral singularities where two or more eigenstates coalesce, resulting in dramatic physical consequences such as enhanced sensitivity and unusual wave dynamics. Although both concepts individually have been extensively explored, the intricate relationship and interplay between BICs and EPs has eluded comprehensive experimental verification until now.
Dielectric metasurfaces—engineered arrays of nanoscale dielectric structures—have become invaluable platforms for manipulating electromagnetic waves with unprecedented precision. Their inherent low loss and high structural tunability render them ideal candidates for studying complex wave phenomena such as BICs and EPs within photonics. The research team exploited these features by fabricating a metasurface design that enables the controlled evolution of a BIC singularity into a two-dimensional exceptional ring through precise angular manipulation of the incident electromagnetic wavevector.
At the heart of their experiment lies the Friedrich–Wintgen interference mechanism, wherein destructive interference between resonant modes facilitates the creation of BICs. By carefully tuning the incident angle of excitation, the team induced symmetry breaking in the system, triggering a transition that transforms the initially localized BIC point into an extended exceptional ring — a closed curve of degeneracies in momentum space. This transition from zero-dimensional singular points to one-dimensional topological features reveals a new dimension in the topological landscape of non-Hermitian photonics.
The research further delves into the complex eigenvalue spectrum of the system, capturing both real and imaginary components of eigenmodes as functions of momentum. This detailed spectral mapping elucidates the nontrivial topology of exceptional rings, reinforcing the connection between interference-induced BICs and non-Hermitian degeneracies. Such insights herald a new era in the dynamic manipulation of photonic states, transcending conventional Hermitian constraints.
Moreover, the team innovatively employed optical pumping techniques to modulate the carrier concentration within silicon components integrated into the metasurface. This approach enables active control over the system’s non-Hermitian properties by dynamically breaking the degeneracy responsible for EP formation. The ability to switch exceptional point configurations on demand constitutes a versatile platform for reconfigurable photonic devices, an advance that holds substantial promise for real-world applications.
Leveraging this mechanism, the researchers subsequently developed a practical terahertz transmission beam deflector capable of dynamic operation via optical pumping. Such a device exemplifies the translation of abstract topological concepts into tangible technological tools, underscoring the impact of fundamental physics on next-generation optoelectronic innovation. This integration of theory and device fabrication heralds a paradigm shift in how light manipulation can be achieved at terahertz frequencies.
The implications of these findings extend across multiple domains, notably in integrated optics where the compactness and tunability of EPs derived from BICs can revolutionize device functionalities. The sensitivity enhancement near exceptional points holds profound potential for ultraprecise sensors capable of detecting minute environmental changes. Additionally, dynamic wavefront shaping facilitated by EP modulation introduces a versatile methodology for on-chip light control, vital for advanced optical communication systems.
This work thus marks a seminal contribution to topological photonics, offering unprecedented control strategies for electromagnetic wave behavior in non-Hermitian regimes. By establishing a connection between bound states in the continuum and exceptional rings, the research opens pathways for engineering complex photonic landscapes with tailored spectral singularities and topological characteristics.
Future exploration is anticipated to expand the operational bandwidth and environmental robustness of such systems, facilitating their integration into scalable optoelectronic circuits and possibly quantum information platforms. The integration of photoswitchability into exceptional point dynamics represents a new horizon in adaptive photonics, where device properties can be programmatically modified in real time.
In summation, the experimental realization of the BIC-to-EP transition within dielectric metasurfaces not only confirms foundational theoretical predictions but also drives forward the practicality of topological photonics in applications ranging from sensing to dynamic light modulation. This nexus of topological physics and materials engineering promises to redefine the capabilities and complexities of photonic devices in the coming years.
Subject of Research: Topological physics of non-Hermitian photonic systems; transition between bound states in the continuum and exceptional points.
Article Title: Photoswitchable exceptional points derived from bound states in the continuum
Web References: https://doi.org/10.1038/s41377-025-02036-0
Image Credits: Caihong Zhang et al.
Keywords
Bound States in the Continuum, Exceptional Points, Non-Hermitian Physics, Dielectric Metasurfaces, Topological Photonics, Terahertz Technology, Optical Pumping, Silicon Photonics, Eigenmode Dynamics, Friedrich–Wintgen Interference, Dynamic Wavefront Control, Integrated Optics
