School of Physics, University of Exeter, Stocker Road, Exeter, EX4 4QL, UK.
QinetiQ Limited, Cody Technology Park, Ively Road, Farnborough, GU14 0LX, UK.
Sci Rep. 2018 May 2;8(1):6924. doi: 10.1038/s41598-018-25057-9.
Terahertz-spectroscopy probes dynamics and spectral response of collective vibrational modes in condensed phase, which can yield insight into composition and topology. However, due to the long wavelengths employed (λ = 300 μm at 1THz), diffraction limited imaging is typically restricted to spatial resolutions around a millimeter. Here, we demonstrate a new form of subwavelength hyperspectral, polarization-resolved THz imaging which employs an optical pattern projected onto a 6 μm-thin silicon wafer to achieve near-field modulation of a co-incident THz pulse. By placing near-field scatterers, one can measure the interaction of object with the evanescent THz fields. Further, by measuring the temporal evolution of the THz field a sample's permittivity can be extracted with 65 μm spatial resolution due to the presence of evanescent fields. Here, we present the first application of this new approach to articular cartilage. We show that the THz permittivity in this material varies progressively from the superficial zone to the deep layer, and that this correlates with a change in orientation of the collagen fibrils that compose the extracellular matrix (ECM) of the tissue. Our approach enables direct interrogation of the sample's biophysical properties, in this case concerning the structure and permittivity of collagen fibrils and their anisotropic organisation in connective tissue.
太赫兹光谱学探测凝聚相中集体振动模式的动力学和光谱响应,这可以深入了解物质的成分和拓扑结构。然而,由于所使用的长波长(在 1THz 时为 λ=300μm),衍射受限成像通常限于毫米左右的空间分辨率。在这里,我们展示了一种新的亚波长超光谱、偏振分辨太赫兹成像形式,它采用光学图案投影到 6μm 厚的硅片上,以实现与共焦太赫兹脉冲的近场调制。通过放置近场散射体,可以测量物体与消逝场的相互作用。此外,通过测量太赫兹场的时间演化,可以提取样品的介电常数,其空间分辨率为 65μm,这是由于存在消逝场。在这里,我们首次将这种新方法应用于关节软骨。我们表明,这种材料的太赫兹介电常数从表面区域到深层逐渐变化,这与组成组织细胞外基质(ECM)的胶原纤维的取向变化相关。我们的方法能够直接询问样品的生物物理特性,在这种情况下,涉及胶原纤维的结构和介电常数及其在结缔组织中的各向异性组织。
