拉曼散射
密度泛函理论
拉曼光谱
材料科学
化学
检出限
吸附
散射
化学物理
化学吸附
硒代半胱氨酸
纳米技术
光化学
咪唑
分子振动
贵金属
光谱学
分子
基质(化学分析)
发色团
纳米颗粒
生物结合
作者
Jia‐Wei Huang,Shu Han,Tian‐Qing Zhang,An Wang,Yinyin Qian,Yi Zhou,Yi-Chuan Kou,Sheng-Hong Liu,Fan‐Li Zhang
出处
期刊:ACS Sensors
[American Chemical Society]
日期:2026-06-04
卷期号:11 (6): 5212-5220
标识
DOI:10.1021/acssensors.6c02215
摘要
Precise in situ monitoring of trace formaldehyde (CH 2 O), a high-risk indoor volatile organic compound (VOC), is critical for public health. However, direct surface-enhanced Raman scattering detection remains a formidable challenge due to the negligible Raman scattering cross-section of CH 2 O and weak adsorption affinity on noble metals. Herein, an ordered Au@ZIF-8 core−shell heterostructure array was developed to achieve efficient “capture-and-enhance” synergistic sensing. Beyond passive physical enrichment, a unique “guest-induced framework response” mechanism was elucidated through 13 C isotope labeling spectroscopy and density functional theory (DFT) simulations. Atomistic calculations reveal that highly electrophilic CH 2 O preferentially binds to deprotonated defect sites within the framework, inducing a localized conformational torsion of the imidazole linkers and a substantial narrowing of the bandgap. This minor structural torsion relaxes spatial symmetry constraints, thereby activating and enhancing specific host vibrational modes that serve as robust Raman signal reporters. By optimizing the array configuration and shell thickness, the localized electromagnetic field was tailored to compensate for the intrinsic scattering deficiencies of CH 2 O. The resulting sensor achieves an ultra-low limit of detection (LOD) of 0.16 ppt and exhibits excellent linearity ( R 2 ≥ 0.99) from 0.01 ppb to 100 ppm. Furthermore, the cooperative synergistic effects of kinetic molecular sieving and localized host−guest chemical chemisorption within the ZIF-8 matrix grant the sensor robust resistance to complex interferences such as ethanol and toluene. This mechanism-driven strategy, leveraging the flexible response of metal-organic frameworks, establishes a new paradigm for the molecular-level identification of trace VOC gases.
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