Leveraging bound states in the continuum for advanced ultra-sensitive sensing technologies.

IF 12.2 2区材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY

Materials Horizons Pub Date : 2025-04-25 DOI:10.1039/d5mh00413f

Dev Kumar Thapa, Soumava Biswas

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Abstract

Traditional sensing methods, such as ELISA, PCR, and electrochemical sensors, face challenges like limited sensitivity, high costs and complex sample preparation. In contrast, optical sensors, particularly surface plasmon resonance (SPR) and dielectric-based guided-mode resonance (GMR) sensors have emerged as promising alternatives. These sensors offer non-invasive measurements, remote readouts, and enhanced sensitivity. While SPR sensors benefit from high local sensitivity, they are limited by energy losses in the metal, reducing the overall quality-factor (Q). On the other hand, GMR sensors, which use low-loss dielectric materials, achieve higher Q factors but are constrained by their inability to effectively detect biomolecules located farther from the sensor surface. Recently, materials that support bound states in the continuum (BICs) have attracted attention for their potential to achieve infinite Q factors, resulting in ultra-narrow resonance linewidths, exceptional precision, and enhanced light-matter interaction. These features make BICs highly promising for sensing applications. This review offers an in-depth understanding of BICs, explaining their principles, including the topological nature of BICs, and exploring recent advancements in BIC-based refractive index sensing technologies. It focuses on material platforms such as dielectric, plasmonic, and hybrid materials that host BICs. Additionally, the review addresses challenges in the field and suggests potential solutions.

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利用连续体中的束缚态来实现先进的超灵敏传感技术。

传统的传感方法，如ELISA、PCR和电化学传感器，面临着灵敏度有限、成本高和样品制备复杂等挑战。相比之下，光学传感器，特别是表面等离子体共振（SPR）和基于电介质的导模共振（GMR）传感器已经成为有希望的替代方案。这些传感器提供非侵入式测量、远程读数和增强的灵敏度。虽然SPR传感器受益于高局部灵敏度，但它们受到金属能量损失的限制，降低了整体质量因子(Q)。另一方面，使用低损耗介质材料的GMR传感器可以实现更高的Q因子，但由于无法有效检测距离传感器表面较远的生物分子而受到限制。最近，支持连续介质束缚态（bic）的材料因其实现无限Q因子的潜力而引起了人们的关注，从而导致超窄的共振线宽，卓越的精度和增强的光-物质相互作用。这些特性使得bic在传感应用中非常有前景。本文综述了对bic的深入了解，解释了它们的原理，包括bic的拓扑性质，并探讨了基于bic的折射率传感技术的最新进展。它侧重于介质、等离子体和混合材料等承载bic的材料平台。此外，该综述还指出了该领域的挑战，并提出了潜在的解决方案。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Materials Horizons CHEMISTRY, MULTIDISCIPLINARY-MATERIALS SCIENCE, MULTIDISCIPLINARY

CiteScore

18.90

自引率

2.30%

发文量

306

审稿时长

1.3 months

期刊介绍： Materials Horizons is a leading journal in materials science that focuses on publishing exceptionally high-quality and innovative research. The journal prioritizes original research that introduces new concepts or ways of thinking, rather than solely reporting technological advancements. However, groundbreaking articles featuring record-breaking material performance may also be published. To be considered for publication, the work must be of significant interest to our community-spanning readership. Starting from 2021, all articles published in Materials Horizons will be indexed in MEDLINE©. The journal publishes various types of articles, including Communications, Reviews, Opinion pieces, Focus articles, and Comments. It serves as a core journal for researchers from academia, government, and industry across all areas of materials research. Materials Horizons is a Transformative Journal and compliant with Plan S. It has an impact factor of 13.3 and is indexed in MEDLINE.