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Bound state in the continuum

A bound state in the continuum (BIC) is a resonant state that remains spatially localized and possesses an infinite lifetime, despite its energy being embedded within the continuous spectrum of extended, radiating modes that typically allow for energy dissipation through radiation. These states arise in various physical systems, including , electromagnetics, acoustics, and , where they defy conventional expectations by avoiding coupling to outgoing waves via mechanisms such as destructive or protection. The concept of BICs was first theoretically proposed in 1929 by and in the context of , demonstrating their existence through a carefully engineered potential that embeds a discrete state within a scattering continuum. Subsequent realizations appeared in diverse wave phenomena, such as acoustic waveguides in 1966 and photonic structures in the , highlighting their generality across scales and media. In ideal theoretical models, BICs exhibit real energy eigenvalues and zero decay rate, but practical implementations often manifest as quasi-BICs with exceptionally high quality factors (Q-factors) approaching infinity under or parameter tuning. Mechanisms enabling BICs include symmetry-protected variants, where structural symmetries decouple the mode from radiation channels (e.g., in periodic slabs); accidental BICs from fine-tuned parameters in low-symmetry systems; and Fabry-Pérot or interference-based types, such as those in coupled resonators or water wave analogs. These properties lead to sharp resonances, enhanced light-matter interactions, and topological features like singularities, making BICs robust against perturbations. In and related fields, BICs have transformative applications, including ultralow-threshold lasing in photonic-crystal surface-emitting lasers, efficient nonlinear frequency conversion (e.g., ), high-sensitivity refractometric sensors exploiting lineshapes, and wavefront manipulation for beam control. They also enable advancements in quantum technologies, such as strong exciton-photon coupling for condensates, and emerging areas like parity-time symmetric and moiré superlattices. Ongoing research continues to explore BICs in acoustic and mechanical systems for and .

Introduction

Definition and Basic Principles

A bound state in the continuum (BIC) is a localized eigenstate whose energy lies within the continuous spectrum of extended, radiating states, yet it remains perfectly confined without decaying into those extended modes. This counterintuitive phenomenon arises because the BIC is decoupled from the radiation channels, preventing energy leakage despite its embedding in the continuum. In contrast to conventional bound states, which have energies below the continuum threshold and are naturally isolated by an energy gap, BICs exist above this threshold but evade coupling through protective mechanisms such as destructive interference or symmetry mismatches. The basic principles of BICs stem from the wave nature of the system, where the localized state coexists with delocalized waves but does not interact with them due to specific conditions that nullify the coupling. For instance, in open systems like resonators, the BIC's amplitude interferes destructively with outgoing waves, effectively trapping the energy indefinitely. This protection can occur naturally in structures with certain symmetries or be engineered via parameter tuning, allowing the state to persist amid the continuum. The concept was first theoretically proposed by and Wigner in , who demonstrated its possibility in quantum mechanical potentials. Intuitively, a BIC can be likened to a on an open pond that remains confined to a small region despite the surrounding water's freedom to propagate waves outward, achieved through precise that cancels any expansion. Key properties of ideal BICs include an infinite lifetime, as there is no decay pathway, and an infinitely high quality factor (Q-factor), reflecting perfect energy confinement. In practice, these states are approached as quasi-BICs with extremely long lifetimes, but the theoretical ideal underscores their unique stability.

Significance in Physics

Bound states in the continuum (BICs) represent a profound challenge to traditional scattering theory in open quantum and wave systems, where states are typically expected to decay due to coupling with extended continua of radiating modes. Instead, BICs achieve perfect confinement by decoupling from the radiation channels, allowing localized modes to persist indefinitely within otherwise leaky environments. This counterintuitive phenomenon arises in diverse physical contexts, including electromagnetics, acoustics, and , highlighting the universal principles governing wave localization in open structures. The implications of BICs for resonances are particularly transformative, as they enable the realization of ultra-high-quality factor (Q-factor) resonances approaching , far surpassing conventional bound states or Fabry-Pérot cavities. Such infinite-Q modes dramatically enhance light-matter interactions, facilitating applications like low-threshold lasers, ultrasensitive sensors, and efficient nonlinear optical devices by concentrating electromagnetic fields over extended durations without radiative losses. For instance, BICs have been shown to boost enhancement by orders of magnitude in nanostructures, underscoring their potential to revolutionize photonic technologies. BICs also connect to foundational phenomena in wave physics, serving as idealized limits of resonances—where destructive suppresses radiation—and exceptional points in non-Hermitian systems, where eigenvalues coalesce and sensitivity peaks. These ties position BICs as precursors that illuminate -driven localization mechanisms, bridging Hermitian and non-Hermitian descriptions of open systems. In contemporary physics, BICs embody a key paradigm for non-Hermitian dynamics, where gain, , and play central roles, and for topological , where symmetry-induced mechanisms shield modes from perturbations. This relevance extends BICs beyond classical waves to quantum and topological , offering robust platforms for exploring protected states and exotic phases in dissipative environments.

Historical Development

Early Theoretical Proposals

The concept of bound states in the continuum (BICs) originated in the context of quantum defect theory, which sought to explain irregularities in atomic spectra arising from short-range deviations in the potential. This motivation highlighted the possibility of states within a continuous of states. In 1948, Kurt O. Friedrichs established a foundational on the perturbation of continuous spectra, demonstrating that embedded eigenvalues could persist or be displaced under weak , provided certain conditions were met; this result underscored the mathematical viability of such states but suggested their rarity in generic potentials. The first explicit theoretical construction of a appeared in 1929, when and Eugene P. Wigner engineered a potential for the one-dimensional that yielded a real, discrete eigenvalue fully embedded in the of extended states. Their approach involved tailoring the potential to finely balance the attractive and repulsive components, ensuring zero coupling to the despite energetic overlap. Extending this idea to three-dimensional , they introduced mechanisms akin to symmetry protection, where spatial symmetries decouple the from radiative channels, preventing decay. Further advancements in the mid-1980s built on these foundations by exploring more accessible realization pathways. In 1985, Hermann Friedrich and Dieter Wintgen proposed interference-based BICs in multichannel quantum scenarios, where destructive between two overlapping resonances suppresses leakage, effectively trapping the state within the continuum. This mechanism, applicable to atomic and molecular systems, offered a contrast to the potential-engineering method of and Wigner by relying on natural multichannel dynamics rather than potentials.

Key Milestones and Experimental Advances

In the late 20th and early 21st centuries, theoretical extensions of bound states in the (BICs) built upon early quantum mechanical proposals, such as the symmetry-protected and parameter-tuned varieties. During the and , researchers explored parameter tuning mechanisms, exemplified by coupled-resonance models that allowed BICs to emerge through fine adjustments in system parameters, extending the 1985 Friedrich-Wintgen framework to photonic contexts. Theoretical work also introduced inverse design methods, where structures were optimized to host BICs by solving inverse problems, enabling targeted realization in waveguides and periodic media. For instance, Fabry-Pérot-like configurations in waveguides were proposed as platforms for parameter-tuned BICs, where between reflected waves creates non-radiating modes embedded in the . The first experimental realizations marked a pivotal breakthrough in the 2010s, transitioning BICs from theory to observation in photonic systems. In 2011, Plotnik et al. demonstrated symmetry-protected BICs in an array of coupled optical waveguides, observing localized modes that did not couple to radiating channels due to symmetry mismatch, confirming the in a two-dimensional photonic . This was followed in 2013 by Hsu et al., who reported single-resonance BICs in slabs, achieved through environmental engineering that decoupled the mode from radiation continua. These experiments validated theoretical predictions and spurred interest in scalable photonic implementations. In the 2020s, advances focused on quasi-BICs—near-ideal states with finite but exceptionally high quality factors—particularly in metasurfaces, enhancing practical utility for light manipulation. By 2020, designs in all-dielectric metasurfaces achieved quasi-BICs with Q-factors exceeding 10^5 through controlled , with subsequent works pushing beyond 10^6, such as a 2023 demonstration reaching Q ≈ 5.1 × 10^6 via symmetry-protected mechanisms in metasurfaces. Topological protections emerged as a robust avenue, with a 2023 study realizing topological BICs in twisted moiré photonic crystals, where moiré patterns induced protected edge states embedded in the for enhanced robustness against disorder. Recent 2024–2025 developments have expanded BICs to novel media, emphasizing room-temperature operability and integration. In 2024, BICs were uncovered in InSb nanowire networks, observed at room temperature through transport measurements revealing localized states within the electronic continuum, leveraging the networks' disordered topology for stability. Concurrently, theoretical and experimental work in 2025 demonstrated BICs in wire media slabs, where arrays of thin metallic wires supported non-radiating electromagnetic modes via spatial dispersion, offering potential for terahertz applications. These milestones underscore the broadening scope of BICs from abstract quantum phenomena, like the original Wigner-von Neumann proposal, to engineered classical wave systems.

Theoretical Foundations

Mathematical Formulation

The mathematical formulation of bound states in the continuum (BICs) originates in through the time-independent for a particle subject to a local potential V(\mathbf{r}): -\frac{\hbar^2}{2m} \nabla^2 \psi(\mathbf{r}) + V(\mathbf{r}) \psi(\mathbf{r}) = E \psi(\mathbf{r}), where \psi(\mathbf{r}) is the wave function, m is the particle , \hbar is the reduced , and E > 0 lies within the continuous of extended states. For such positive energies, the spectrum is typically continuous, corresponding to scattering states that are delocalized and satisfy outgoing conditions at spatial infinity, such as asymptotically behaving as plane waves or spherical waves (e.g., \psi(\mathbf{r}) \sim e^{i k r} with k = \sqrt{2mE}/\hbar in one dimension, or Hankel functions in higher dimensions). A emerges as a special eigenstate solution to this equation where the wave function remains localized despite the E embedding in the ; specifically, \psi(\mathbf{r}) is square-integrable (\int |\psi(\mathbf{r})|^2 d\mathbf{r} < \infty), ensuring normalizability and confinement without decay into the surrounding extended states. This localization occurs while formally satisfying the outgoing radiation boundary conditions required for scattering solutions, yet with zero net radiation flux, as the potential V(\mathbf{r}) is tuned such that the amplitude vanishes at infinity. In classical wave systems, such as acoustics or electromagnetics, the analogous framework employs the Helmholtz equation for monochromatic waves: \nabla^2 \phi(\mathbf{r}) + k^2 \phi(\mathbf{r}) = 0, with wavenumber k = \omega / c > 0 (where \omega is the real frequency and c the wave speed) falling in the continuum of propagating modes, and subject to Sommerfeld radiation conditions at infinity to select outgoing waves (e.g., \phi(\mathbf{r}) \sim e^{i k r}/r in three dimensions). Here, a BIC is a normalizable solution (\int |\phi(\mathbf{r})|^2 d\mathbf{r} < \infty) that coexists with radiating continuum modes but exhibits no leakage, maintaining perfect confinement. The stability of an exact BIC against perturbations is characterized by conditions ensuring zero radiation, such as the vanishing divergence of the group velocity field or at the BIC parameter point, which protects the state from coupling to the continuum.

Conditions for BIC Existence

Bound states in the continuum (BICs) exist only under specific conditions that prevent coupling between the localized mode and the radiating continuum, primarily through mechanisms that enforce zero radiation loss. One fundamental condition is destructive interference among multiple radiation channels, where the far-field amplitudes from different pathways cancel each other out, resulting in no net energy leakage. This interference typically arises when the phases and amplitudes of outgoing waves are precisely balanced, such that the total radiated power vanishes. Another key condition involves symmetry mismatch between the BIC mode and the continuum states. If the BIC possesses a different parity, rotational symmetry, or other group representation compared to the available radiation channels, it becomes decoupled from the continuum, prohibiting energy transfer. For instance, an odd-parity mode in a symmetric structure cannot couple to even-parity plane waves, ensuring the BIC's isolation. Topological protection provides an additional robustness to these conditions, where BICs are characterized by nonzero topological invariants such as winding numbers or Chern numbers. These invariants, defined by the winding of the far-field polarization vector around the BIC in parameter space, guarantee the BIC's existence and stability against perturbations unless the topological charge is annihilated. The winding number q, for example, quantifies this protection, with typical values like q = \pm 1 or \pm 2 ensuring the BIC persists over extended regions. A fundamental result in scattering theory imposes a limitation, stating that BICs cannot exist in generic, compact potentials for single-particle systems because any embedded eigenstate would inevitably couple to the far-field continuum and radiate. Overcoming this requires deliberate fine-tuning of parameters or engineered structures to satisfy the interference or symmetry conditions. In practical finite systems, exact BICs are inaccessible, leading to quasi-BICs with finite but arbitrarily high quality factors Q. The quality factor scales as Q \propto 1/\epsilon^2, where \epsilon represents the detuning from the exact BIC condition, such as a small symmetry-breaking perturbation or parameter mismatch. This quadratic divergence allows quasi-BICs to achieve Q > 10^6 in engineered photonic structures.

Classification of BICs

BICs from Inverse Problem Solving

Bound states in the continuum (BICs) can be engineered through solving, where system parameters such as potentials, hopping rates, or boundary geometries are designed to embed a localized state within a of extended modes. This approach inverts the typical forward problem of solving for eigenstates given a fixed , instead specifying a desired bound wavefunction and deriving the required structure to support it without radiation leakage. Such methods ensure the BIC eigenvalue is real and lies above the threshold, achieving perfect confinement theoretically. Potential engineering involves modifying the potential V(\mathbf{r}) in the (or analogous wave equations) to produce a real eigenvalue embedded in the continuum. By constructing a potential that supports a prescribed oscillating wavefunction, such as one that interferes destructively with outgoing waves, a forms at an energy above the scattering threshold. The for this is the 1929 proposal by and Wigner, who demonstrated the existence of such potentials mathematically. In tight-binding models, hopping rate engineering tunes inter-site couplings to eliminate leakage from the bound state into the continuum. For instance, in one-dimensional chains, alternating hopping rates between sites can generate flat bands that manifest as BICs, where the eigenmode localizes perfectly due to destructive interference in propagation. This has been realized experimentally in arrays of coupled optical waveguides, confirming zero decay rates for the embedded states. Boundary shape engineering designs irregular interfaces or obstacles to trap modes within open waveguides or channels. By shaping boundaries to align with the streamlines of a desired non-radiating solution, the structure supports a BIC that coexists with propagating modes but remains decoupled. An example is in two-dimensional water wave systems, where submerged obstacles are contoured to produce trapped modes at specific wavenumbers, demonstrating non-uniqueness in the linear wave problem.

BICs from Parameter Tuning

Bound states in the continuum (BICs) from parameter tuning emerge when system parameters, such as energy levels, geometric dimensions, or material properties, are adjusted to induce destructive among radiating components, thereby suppressing to the continuum. This forward engineering approach involves varying these parameters to align resonances such that their outgoing waves cancel, resulting in a localized state with infinite lifetime embedded within the continuum spectrum. Unlike inverse design methods that optimize structures from desired outcomes, parameter tuning starts from existing configurations and iteratively refines them to reach the BIC condition. In single-resonance parametric BICs, a solitary is decoupled from the through detuning, where parameters like spacing or slab thickness are adjusted to nullify the radiation loss of that . For instance, in slabs, tuning the structural parameters shifts the relative to the light line, causing the far-field radiation pattern to vanish at specific in-plane momenta. This leads to a in the radiative factor Q_r as the tuning approaches the critical point. Mathematically, this is reflected in the \mathbf{k}(\omega), where the wavevector component perpendicular to the structure satisfies the condition for zero radiation at the BIC point, embedding the state above the without leakage. For multi-resonance cases, tuning facilitates between multiple nearly degenerate states, where their collective amplitudes destructively interfere to form a . This occurs when the detuning between resonances is finely adjusted to balance their strengths and rates, effectively trapping within the system. Near the tuning point, the quality factor scales inversely with the square of the detuning \delta, as Q \propto 1/|\delta|^2, highlighting the sensitivity and sharpness of the BIC formation. Accidental BICs generated via parameter tuning exhibit varying robustness depending on their topological protection; those with nonzero topological charge are resilient to small or fabrication imperfections, maintaining high Q factors, whereas unprotected ones degrade rapidly under perturbations. In contrast, symmetry-protected BICs offer inherent stability but require precise preservation. This tunability makes parameter-induced accidental BICs valuable for applications requiring adjustable confinement, though their sensitivity to necessitates careful control in practical realizations.

Symmetry-Protected and Separable BICs

Symmetry-protected bound states in the continuum (BICs) arise when the of a localized mode is incompatible with that of the radiating channels, preventing and ensuring infinite lifetime. This protection typically occurs due to a mismatch in the irreducible representations of the point group between the BIC and the modes, such as even-odd differences that forbid matrix elements for radiation. For instance, in systems with mirror , an odd- mode cannot couple to even-parity plane waves, embedding the state within the without decay. In separable BICs, the decouples into independent variables, allowing s isolated in one while embedded in a in others. This is exemplified in systems using coordinates like cylindrical ones, where conservation isolates states from radial continua, as in theoretical models of quantum wells or two-dimensional equations. Such separability enables exact solutions where the bound state remains decoupled despite energetic overlap with extended modes. Topological aspects enhance the robustness of these BICs, particularly at band edges where they exhibit nonzero winding numbers, acting as polarization or phase vortices with conserved topological charges. These charges ensure stability against perturbations, requiring symmetry-breaking changes to annihilate the BIC, and link to broader topological invariants like Chern numbers in periodic systems. Examples include two-dimensional lattices with C_{nv} symmetry (n ≥ 2), where high-order rotational invariance supports multiple degenerate symmetry-protected BICs at high-symmetry points like the Γ point. For C_6 symmetry, pairs of BICs emerge due to the multiplicity of irreducible representations, enabling robust confinement. Parameter tuning near these symmetry points can approach but not fully realize the BIC without breaking the protective symmetry.

Specific BIC Types

Wigner-von Neumann BICs

The concept of bound states in the continuum (BICs) was first theoretically proposed in 1929 by and , who demonstrated their existence through the engineering of a tailored potential designed to embed a localized state within the continuous of extended states. Their approach involved solving an inverse eigenvalue problem, where the potential is constructed to support a pre-specified bound wavefunction at an embedded in the , defying the conventional expectation that such states would decay via coupling to radiating modes. In the first canonical case, and Wigner considered a one-dimensional finite-range potential augmented by an oscillatory tail, which creates an exact at a specific positive . The oscillatory tail induces destructive interference in the wavefunction tails, preventing leakage and ensuring the state remains bound despite coexisting with the continuum of scattering states. The second canonical case extends to three dimensions, featuring a radial potential combined with the barrier, where the BIC emerges through tuning of the centrifugal term in the effective potential. Here, the yields a BIC wavefunction of the form \psi(r) = f(r) \frac{\sin(kr)}{kr}, where f(r) is a real envelope function that decays at large r (e.g., f(r) \propto 1/(kr)^4) to ensure normalizability, even though the energy E = k^2/2 > 0 lies within the continuum spectrum. These Wigner-von Neumann BICs, however, rely on highly artificial and non-physical fine-tuning of the potential parameters, rendering them extremely sensitive to any perturbations, which generally broaden the state into a short-lived resonance rather than a true bound state.

Friedrich-Wintgen BICs

Friedrich and Wintgen introduced a class of bound states in the continuum (BICs) in 1985, arising from the destructive interference of resonances associated with different bound subsystems that couple to the same continuum channel. This mechanism enables a localized state to persist without decay, even when its energy lies within the continuum spectrum, by canceling the radiative loss through phase opposition. The underlying process relies on the between a narrow bound core state and a broader resonant state embedded in the , where the to the open channel results in complete suppression of the decay width at a specific parameter value. In , this manifests as trapped states where autoionization is inhibited despite the availability of decay pathways. Mathematically, the model employs Feshbach's projection approach for a two-channel , described by a non-Hermitian effective that incorporates between discrete states and the . The takes the form H = \begin{pmatrix} E_1 - i \Gamma_1 / 2 & V \\ V & E_2 - i \Gamma_2 / 2 \end{pmatrix}, where E_1, E_2 are the unperturbed energies, \Gamma_1, \Gamma_2 are the decay widths, and V is the off-diagonal coupling; the BIC emerges when the interference condition sets the effective width to zero. A key quantity is the transmission amplitude through the system, expressed as t(\varepsilon) = \frac{\varepsilon - i \Gamma / 2}{\varepsilon - i (\Gamma / 2 + \delta)}, which vanishes at \delta = -\Gamma / 2, corresponding to the point of perfect destructive interference and the BIC. Here, \varepsilon is the energy detuning, \Gamma the total width, and \delta a tunable detuning parameter. Proximate to the BIC, the scattering profiles display asymmetric Fano lineshapes, reflecting the coherent superposition of resonant and non-resonant pathways. Such signatures have been experimentally observed in atomic systems, such as suppressed linewidths in Rydberg atoms. This framework extends to multichannel open systems, where multiple resonances can interfere across several decay channels, enabling higher-order BICs when the number of internal modes exceeds the available channels.

Fabry-Pérot BICs

Fabry-Pérot bound states in the continuum (BICs) arise in open structures analogous to traditional Fabry-Pérot cavities, where modes are embedded within a of propagating modes. These setups typically involve open cavities or waveguides flanked by partially reflecting mirrors or defect layers, such as in photonic crystals with two anisotropic defect layers acting as mirrors, allowing modes to lie within the propagation band of the surrounding medium. In such configurations, the cavity length L and are key parameters, enabling the resonant modes to interact with the external while potentially achieving perfect confinement. The mechanism for forming Fabry-Pérot BICs relies on parametric tuning of the cavity parameters, such as length or , to induce symmetric radiation patterns that interfere destructively, effectively canceling leakage into the . This tuning ensures the resonant becomes orthogonal to the radiating channels, preventing escape despite embedding in the . A critical resonance condition for the BIC is given by $2kL + \phi = 2\pi n, where k is the wavevector in the , L is the cavity length, \phi accounts for shifts from the mirrors, and n is an integer; at grazing incidence, this condition aligns the frequency with the edge, enhancing . Unlike parameter tuning in other BIC classes, here the focus is on cavity-specific adjustments to achieve round-trip alignment that suppresses . These BICs are particularly prevalent in photonic structures, including coupled waveguides and anisotropic photonic crystals, where they exhibit infinite factors (Q \to \infty) at the exact tuning point due to zero radiative loss. In practice, quasi-BICs are realized through slight detuning, yielding high but finite Q-factors (e.g., Q \approx 10^6) with strong field localization between the mirrors. This contrasts with standard Fabry-Pérot resonators, which inherently suffer from leakage through imperfect mirrors, whereas Fabry-Pérot BICs achieve no leakage at the precise parameter values owing to the mode's to the channels, enabling ideal trapping without physical isolation.

Applications and Realizations

In Photonics and Metamaterials

Bound states in the continuum (BICs) enable enhanced light confinement in photonic structures by supporting quasi-BICs with extremely high quality factors (Q-factors), which localize electromagnetic fields far beyond diffraction limits. In dielectric metasurfaces, these modes achieve Q-factors exceeding 10^5, such as 101,000 in shallow-etched silicon pairs operating in the telecom range at 1560 nm, facilitating strong light-matter interactions with reduced radiative losses. This confinement has been leveraged to reduce lasing thresholds; for instance, a nanolaser based on merging BICs in a photonic crystal slab demonstrated a threshold of 1.47 kW/cm² with a total Q-factor up to 4.9 × 10^5, enhancing emission efficiency through Purcell effects up to 17.74(λ/n)^3 modal volumes. Similarly, amplified emission in asymmetric dielectric metasurfaces via eigenfield perturbation has enabled lasing with Q-factors approaching 10^6, promoting applications in compact optical sources. In sensing applications, BICs produce sharp Fano resonances in metasurfaces, enabling ultra-sensitive detection. Dielectric gratings supporting BICs exhibit sensitivities up to 701 nm/RIU, as demonstrated in pixelated metasurfaces for detecting femtomolar biomolecular solutions via Fano dips with linewidths below 1 nm. The (FOM = sensitivity / linewidth) is optimized near normal incidence, with perturbative models yielding maximum sensitivities of S_max = (λ_BIC / n_c) × (A_clad / A_total), where field overlap with the cladding maximizes response to index changes. Chiral metasurfaces further enhance this, achieving phase-detection sensitivities of 1220 THz/RIU through BIC-driven variations in transmission phase. Topological devices utilize BIC-protected edge states in photonic crystals to create robust waveguides immune to backscattering and defects. In all-dielectric photonic crystals, bound topological edge states in the continuum form at air interfaces, confining light unidirectionally with Q-factors around 1.6 × 10^5 and asymmetric ratios exceeding 27 , ensuring stability over sharp bends. These states, arising from valley-Hall , enable one-way waveguiding in valley photonic crystals, with experimental realizations showing robustness against fabrication imperfections. Recent examples highlight in all-dielectric structures for advanced control. A 2023 review details hybrid metasurfaces in regimes, achieving Q-factors 14.6 times higher than conventional designs through symmetry-protected modes in arrays. In 2024, moiré in twisted bilayer photonic crystal slabs enabled broadband resonance control, with infinite Q at the Γ point and slow decay (e.g., Q ≈ 9000 at 3.6° incidence), allowing wide-angle (up to ±90°) manipulation via topological charge alignment. Experimental visualization of BIC modes relies on near-field scanning techniques to probe non-radiative fields. (CL) and (EELS) in map BIC localization in nanoantenna arrays, revealing "true" BICs at 720 nm with no far-field radiation but strong near-field enhancement over at least six unit cells. Scattering-type scanning near-field optical (s-SNOM) further resolves quasi-BIC formation in metasurfaces, confirming subwavelength confinement and protection in as few as 10 × 10 unit cells.

In Quantum Mechanics and Other Domains

In quantum mechanics, bound states in the continuum (BICs) have been explored to create stable quantum states in open systems, particularly for quantum dots and atomic systems where decoherence poses a significant challenge. In pairs of open quantum dots connected by a wire, BICs of single electrons form at nearly periodic distances between the dots due to interference of waves reflected from each dot, resulting in states that are robust against perturbations in system parameters. These localized electron states embedded in the scattering continuum suppress spontaneous emission and decay, offering potential for long-lived qubits by minimizing coupling to radiative channels. Similarly, in atomic-like systems modeled as giant atoms—quantum emitters coupled to a structured environment at multiple points—BICs arise from engineered interference, enabling decoherence avoidance in two-dimensional lattices of coupled cavities. This mechanism protects quantum coherence, with applications in quantum information processing where BICs facilitate infinite-lifetime modes that decouple from the continuum, thus stabilizing qubit operations against environmental dissipation. Acoustic BICs enable efficient sound trapping in metamaterials, with implications for by confining waves without loss. In coupled Helmholtz resonators, BICs emerge as quasilocalized modes within the propagating , achieved through symmetry-protected or accidental that yields infinite lifetimes for resonant states. These structures support subwavelength-scale wave manipulation, allowing for broadband absorption and suppression of unwanted acoustic propagation in environments like barriers. In mechanical systems, vibrational BICs facilitate by localizing flexural waves in plates and resonators with exceptionally high quality factors. Friedrich-Wintgen BICs, formed by destructive of degenerate modes, have been explored in elastic metamaterials for . In thin elastic plates, symmetry-protected BICs in metaplate designs confine flexural waves through parameter tuning, enabling compact structures for harvesting ambient from sources like machinery vibrations without leakage to the . This localization enhances , making BICs promising for self-powered sensors and sustainable mechanical devices. Beyond these areas, BICs have been observed in InSb networks under ballistic and perpendicular , manifesting as conductance resonances or antiresonances tunable by and field strength. In hashtag-like network geometries, these states arise from interference in the , with Rashba spin-orbit effects modulating visibility but enabling spin-filtered for spintronic applications. In , BICs represent embedded resonances in the of scattering states, populated through theoretical models of and hadronic interactions, offering insights into states amid channels. Cross-domain analogies arise from the shared mathematical structure of wave equations governing quantum, acoustic, and mechanical systems, allowing concepts—such as interference-induced decoupling—to transfer seamlessly; for example, symmetry-protected mechanisms in quantum dots parallel those in flexural plates, unifying design principles across fields.

Challenges and Future Directions

Current Limitations

Exact (BICs) are inherently fragile and exhibit high sensitivity to structural , where even small perturbations can induce radiation losses and transform ideal BICs into quasi-BICs with finite factors (Q-factors). In practical realizations, such as all-dielectric metasurfaces, fabrication tolerances on the nanometer scale—typically deviations of a few nanometers in dimensions—severely limit the achievable Q-factors, as precise control is challenging due to imperfections in and processes. Studies on chains of Mie resonators demonstrate that the radiative Q-factor of symmetry-protected BICs decreases linearly with increasing amplitude (σ), becoming dominant over finite-size effects at σ ≈ 0.05, highlighting the need for sub-2% structural uniformity to maintain high confinement. Real-world implementations of BICs are further constrained by finite Q-factors arising from inherent losses and material absorption, preventing the theoretical infinite from being realized. In all- structures, such as silicon-based metasurfaces, ohmic losses and absorption in the dielectric medium introduce non-radiative , capping experimental -factors at relatively low values despite ideal predictions, and resulting in asymmetric line shapes indicative of leaky modes. For instance, Fabry-Pérot BICs are particularly vulnerable, converting to quasi-BICs through second-order processes induced by material losses that break time-reversal . Scalability poses a significant challenge for -based devices, with extensions from two-dimensional () photonic crystals or metasurfaces to three-dimensional () structures proving difficult due to increased fabrication complexity and uniformity requirements across larger volumes. While platforms benefit from planar processing techniques, 3D photonic crystals demand precise control over multilayer stacking and isotropic properties, often leading to amplified effects and reduced BIC robustness in volumetric designs. This limitation hinders applications requiring bulk integration, such as compact optical cavities. Theoretical understanding of BICs remains incomplete, particularly in the absence of a general classification framework for hybrid mechanisms that combine symmetry-protected, accidental, and interferometric origins. Current models adequately describe pure cases but struggle with predicting behaviors in systems exhibiting coupled multipolar or extrinsic-intrinsic interactions, leaving gaps in robustness analysis for complex periodic structures. Experimentally detecting true infinite-Q BICs demands near-ideal conditions, including infinite periodic extent and lossless materials, which are unattainable in finite laboratory setups, often resulting in indirect inference through extrapolated Q-factors from quasi-BIC spectra. High-precision characterization techniques, such as angle-resolved , are essential but susceptible to environmental perturbations, further complicating verification of BIC confinement.

Emerging Research Areas

Recent advancements in bound states in the continuum (BICs) are exploring configurations that integrate symmetry protection with features to create robust quasi-BICs, particularly in where and play significant roles. These BICs leverage topological invariants to enhance stability against perturbations, enabling high-quality factor resonances in systems like (QED) with topological atoms. For instance, symmetry-protected light-matter interactions in such setups have demonstrated quasi-BICs with tunable lifetimes, offering potential for active photonic devices. In plasmonic-photonic , symmetry-protected BICs achieve ultrahigh Q-factors, combining electromagnetic for robustness in lossy environments. Topological transformations via subsymmetry further convert boundary states into BICs, providing a pathway for engineering modes in active metasurfaces. Non-Hermitian extensions of BICs are gaining traction, particularly at exceptional points () within parity-time ()-symmetric systems, where gain-loss balance leads to novel resonant behaviors. In non-Hermitian models, a continuum of bound states emerges, defying Hermitian quantization rules and enabling continuous spectra of localized modes. Topological BICs in non-Hermitian lattices exhibit robustness against , observed in Fabry-Pérot configurations with Q-factors up to 10^4. PT-symmetric setups allow BICs to coexist with EPs, where modes split into lasing states carrying topological charges, facilitating switchable singularities via photosensitive materials. Anti-PT-symmetric optical systems realize BICs at EPs, enhancing sensitivity in non-reciprocal devices. These extensions promise applications in tunable lasers and sensors by exploiting EP-enhanced light-matter interactions. Quantum analogs of BICs are being investigated in platforms like cold atoms and superconducting circuits to simulate and probe continuum-embedded states. In arrays of quantum emitters, such as cold atomic ensembles, BICs manifest as non-radiating modes, with lifetimes extended by , analogous to photonic counterparts. Superconducting circuits enable the generation of BIC-like bound states through non-Markovian dynamics, where multiqubit entanglement persists amid dissipation, achieving above 90% in . These analogs facilitate quantum of BIC robustness, bridging wave physics with protocols. Looking toward 2025 and beyond, moiré and architectures are enabling tunable BICs with flat-band dispersions for dynamic control. Optical moiré patterns in twisted slabs produce quasibound states with Q-factors over 10^6, tunable via twist angle for vortex generation. Integration with (AI) for inverse design accelerates BIC optimization, using to predict high-Q metasurfaces from target spectra, reducing design iterations by orders of magnitude. These trends support reconfigurable devices with subwavelength precision. Broader impacts of these emerging BIC paradigms extend to quantum computing and sensing, surpassing current limitations in coherence and sensitivity. Topological BICs in quantum Hall analogs enhance protection against decoherence in hybrid platforms. In sensing, BIC-enabled metasurfaces achieve refractive index detection limits of 10^{-5} RIU, with non-Hermitian extensions amplifying responses at EPs for beyond-state-of-the-art precision in biochemical assays. Recent miniaturized BIC biosensing systems have demonstrated detection limits down to 10^{-5} refractive index units and 129 attomolar (aM) concentrations of extracellular vesicles in clinical samples. These developments herald transformative roles in fault-tolerant quantum processors and ultra-sensitive detectors.