Synthesized complex-frequency excitation for ultrasensitive molecular sensing

IF 27.2 Q1 OPTICS eLight Pub Date : 2024-01-05 DOI:10.1186/s43593-023-00058-y
Kebo Zeng, Chenchen Wu, Xiangdong Guo, Fuxin Guan, Yu Duan, Lauren L. Zhang, Xiaoxia Yang, Na Liu, Qing Dai, Shuang Zhang
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Abstract

Sensors have emerged as indispensable analytical tools across a wide range of important fields, encompassing environmental monitoring, food safety, and public health. They facilitate early disease diagnosis, personalized medicine, and rapid detection of toxic agents. However, detecting trace molecules remains a significant challenge. Surface-enhanced infrared absorption (SEIRA) based on plasmonic nanostructures, particularly graphene, has emerged as a promising approach to enhance sensing sensitivity. While graphene-based SEIRA offers advantages such as high sensitivity and active tunability, intrinsic molecular damping weakens the interaction between vibrational modes and plasmons. Here, we demonstrate ultrahigh-sensitive molecular sensing based on synthesized complex-frequency waves (CFW). Our experiment shows that CFW can amplify the molecular signals (silk protein monolayer) detected by graphene-based sensor by at least an order of magnitude and can be universally applied to molecular sensing in different phases. Our approach is highly scalable and can facilitate the investigation of light-matter interactions, enabling diverse potential applications in fields such as optical spectroscopy, biomedicine and pharmaceutics.

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用于超灵敏分子传感的合成复频激发技术
摘要 传感器已成为环境监测、食品安全和公共卫生等众多重要领域不可或缺的分析工具。它们有助于早期疾病诊断、个性化医疗和有毒物质的快速检测。然而,检测痕量分子仍然是一项重大挑战。基于等离子体纳米结构(尤其是石墨烯)的表面增强红外吸收(SEIRA)已成为提高传感灵敏度的一种有前途的方法。虽然基于石墨烯的 SEIRA 具有高灵敏度和主动可调谐性等优点,但固有的分子阻尼削弱了振动模式与质子之间的相互作用。在此,我们展示了基于合成复频波(CFW)的超高灵敏度分子传感。实验表明,复频波可以将石墨烯传感器检测到的分子信号(丝蛋白单层)放大至少一个数量级,并可普遍应用于不同阶段的分子传感。我们的方法具有高度可扩展性,可促进光-物质相互作用的研究,从而在光学光谱学、生物医学和制药学等领域实现多种潜在应用。
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CiteScore
30.40
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