双折射
极化率
材料科学
各向异性
光学各向异性
光学透明度
红外线的
光学
光电子学
化学物理
极化(电化学)
透明度(行为)
折射率
远红外
凝聚态物理
分子物理学
非线性光学
光学材料
设计要素和原则
红外光谱学
微波食品加热
超短脉冲
作者
Ming‐Zhi Zhang,C Hu,Yi Shan,Jiang‐Gao Mao
摘要
ABSTRACT Birefringent crystals with transparency spanning the mid‐ to far‐infrared regions are critical for infrared optical technologies. However, their development remains constrained by the inherent challenge of simultaneously achieving high birefringence and a broad IR transmission window. Taking the thiophosphate Nb 4 P 2 S 21 , characterized by birefringence‐active S–S units, as a template, we developed a linear‐matching strategy to enhance its optical anisotropy. This approach involves retaining the strongly anisotropic [Nb 2 PS 10 ] backbone while replacing the highly flexible C 2 v ‐symmetric [S 3 ] 2− bridging units with D ∞ h ‐symmetric [LiS 2 ] 3− and [S 2 ] 2− groups, which possess lower polarizability anisotropy. Although such a high‐to‐low substitution typically reduces birefringence, the rigid linear groups couple effectively with the chain, resulting in enhanced birefringence of 0.45 and 0.53 at 546 nm for CsLiNb 4 P 2 S 20 and Nb 4 P 2 S 20 , respectively. Moreover, both crystals exhibit broad infrared transparency (2.5–16.7 µm), and are air stable, highlighting their potential applications as mid‐ to far‐infrared birefringent optical materials. Our design strategy provides a new perspective for the design of crystals with large birefringence.
科研通智能强力驱动
Strongly Powered by AbleSci AI