ORMOCHALC复合材料高效中波长红外(MWIR)偏振器,具有更好的热机械稳定性和光谱选择性

Md. Didarul Islam, Sipan Liu, J. Derov, A. Urbas, Z. Ku, Amy Sihn, Evan M. Smith, D. Boyd, Woohong Kim, J. Sanghera, V. Nguyen, J. Myers, C. Baker, J. Ryu
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A parametric study to choose suitable geometry for the polarizer was conducted, and highly efficient devices were designed that possess competitive extinction coefficients to the commercial polarizers. However, a significant limitation of the ORMOCHALC polymer is that to increase the refractive index of the polymer, the chalcogenide (i.e., S) content needs to be increased, which results in reduced Young’s modulus and lower glass transition temperature. This decayed thermomechanical stability compromises the structural integrity of ORMOCHALC optical devices. In addition to polymeric MWIR polarizer fabrication, composite materials were also synthesized and characterized for future MWIR device fabrications. Poly(S-r-DIB) was reinforced with zinc sulfide nanoparticles to simultaneously improve the refractive index and the thermomechanical properties. 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引用次数: 0

摘要

中波长红外(MWIR, λ = 3-5 μm)材料在军事、工业和非侵入性医疗诊断的光学传感器和器件中具有重要的应用价值。具体来说,MWIR偏振法显著改善了生物识别和伪装检测。大多数商用偏光片都是基于昂贵的无机材料,这些材料很重,易碎,易碎。因此,需要一种适合于MWIR光学的聚合物材料。本文利用硫基有机改性硫族化合物(ORMOCHALC)聚合物通过简单的热印迹法和Ay沉积制备了MWIR偏振片。对偏振片的几何形状进行了参数化研究,设计出了具有与商用偏振片相竞争消光系数的高效器件。然而,ORMOCHALC聚合物的一个显著限制是,为了增加聚合物的折射率,需要增加硫族化合物(即S)的含量,这导致杨氏模量降低和玻璃化转变温度降低。这种衰减的热机械稳定性损害了ORMOCHALC光学器件的结构完整性。除了聚合物MWIR偏振器的制造,复合材料也被合成和表征为未来的MWIR器件的制造。采用硫化锌纳米粒子对Poly(S-r-DIB)进行增强,可同时改善其折射率和热力学性能。ZnS纳米粒子的加入显著提高了ORMOCHALC的玻璃化转变温度(Tg)(9.6℃~ 31.4℃)和折射率(Δn = 6.6%)。在此基础上,分析了基于光学增强和机械增强复合材料的亚波长线栅偏振片的优劣图。如果制造,纳米粒子增强偏振片将具有优越的结构完整性,由于更高的玻璃化转变温度。此外,当ZnS增强ORMOCHALC复合材料的透射-反射曲线的共振波长红移到更大的波长时,极化器表现出光谱选择性。这些偏振片具有优越的消光系数,光谱选择性和改进的热机械稳定性,在MWIR光学中展示了边界实现的机会。
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Highly Efficient Mid-Wavelength Infrared (MWIR) Polarizer by ORMOCHALC Composite With Improved Thermomechanical Stability and Spectral Selectivity
Mid-wavelength infrared (MWIR, λ = 3–5 μm) materials are of great importance due to their applications in optical sensors and devices for military, industry, and non-invasive medical diagnostics. Specifically, MWIR polarimetry has significantly improved biometric recognition and camouflaged detection. Most commercial polarizers are based on expensive inorganic materials that are heavy, fragile, and brittle. Thus a suitable polymeric material for MWIR optics is highly desired. Herein, sulfur-based organically modified chalcogenides (ORMOCHALC) polymers have been utilized to fabricate MWIR polarizers by a simple thermal imprinting method followed by Ay deposition. A parametric study to choose suitable geometry for the polarizer was conducted, and highly efficient devices were designed that possess competitive extinction coefficients to the commercial polarizers. However, a significant limitation of the ORMOCHALC polymer is that to increase the refractive index of the polymer, the chalcogenide (i.e., S) content needs to be increased, which results in reduced Young’s modulus and lower glass transition temperature. This decayed thermomechanical stability compromises the structural integrity of ORMOCHALC optical devices. In addition to polymeric MWIR polarizer fabrication, composite materials were also synthesized and characterized for future MWIR device fabrications. Poly(S-r-DIB) was reinforced with zinc sulfide nanoparticles to simultaneously improve the refractive index and the thermomechanical properties. The addition of ZnS nanoparticles significantly improved the glass transition temperature (Tg) of the ORMOCHALC (9.6 °C to 31.4 °C), and the refractive index (Δn = 6.6 %). Then, a figure of merit subwavelength wire-grid polarizers was also analyzed based on the optically and mechanically reinforced composites. If fabricated, nanoparticles reinforced polarizers will possess superior structural integrity due to higher glass transition temperature. Moreover, the polarizers show a spectral selectivity as the resonance wavelength of the transmitted-reflected curve was redshifted to larger wavelengths for ZnS reinforced ORMOCHALC composite. These polarizers with superior extinction coefficient, spectral selectivity, and improved thermomechanical stability demonstrate a border implementation opportunity in the MWIR optics.
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