太赫兹辐射
生物分子
材料科学
圆二色性
手性(物理)
光谱学
太赫兹光谱与技术
各向异性
分析物
光电子学
光子学
线性二色性
声子
联轴节(管道)
分辨率(逻辑)
光学
二色性
光谱分辨率
纳米技术
超材料
化学物理
宽带
分子物理学
石墨烯
作者
Yijia Zang,Peng Shen,Yao Lu,Jiawei Zhang,Jiwei Qi,Chengwei Song,Fei Fan,Shengjiang Chang,Qiang Wu,Jingjun Xu
摘要
Terahertz (THz) spectroscopy, a label-free and noninvasive tool that is used to resolve the characteristic information of biomolecules, has attracted extensive attention in both physics and biochemistry. However, the traditional THz time-domain spectroscopy (THz-TDS) systems are constrained by linear polarization, disregarding the analyte chirality information that is vital for conducting biomedical analyses in the food and pharmaceutical industries. Here, we develop a technique called THz eigenmode-fingerprint chiroptical spectroscopy (TEFCS) on an achiral gradient metasurface (AGM) platform, enabling the unambiguous resolution of heterogeneous chiral biomolecule mixtures (constituents, chiralities, and ratios). The THz chiral phonon signals can be spectrally consistent and significantly enhanced due to the optimized spectral overlap between the broadband AGM resonances and the biomolecule chiral phonons, resulting in augmented eigen circular dichroism (CD) spectra. The enhanced photon‒phonon coupling scheme in the AGM‒biomolecule system is understood via the anisotropic coupled oscillator theory and gives rise to a substantial sensitivity improvement. These findings provide new insights into integrated bioanalyses and pharmaceutical applications.
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