Highly Stable and Reversible Birefringent Switching Triggered by Thermally Stimulated Phase Transition

IF 6.1 1区化学 Q1 CHEMISTRY, INORGANIC & NUCLEAR

Inorganic Chemistry Frontiers Pub Date : 2025-05-01 DOI:10.1039/d5qi00625b

Cheng Chen, Yunjie Bai, Qi Shi, Mingye Han, Bingbing Zhang, Ying Wang

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Abstract

Manipulating light polarization in birefringent crystals is central to photonic applications. However, controlling intrinsic optical anisotropy in a noninvasive manner remains challenging. Here, we discovered the polymorphism of inorganic birefringent crystal KCe(SO4)2. and P21/c -KCe(SO4)2 crystals can be obtained through polymorph -controllable synthesis. Interestingly, -KCe(SO4)2 exhibits reversible phase transition during which the birefringence value varies by up to 50%. The material is highly stable and the birefringence alteration stimulated by thermally induced phase transition is reversible for over 10 cycles, demonstrating its potential as a birefringence switch. We reveal that the optical anisotropy of KCe(SO4)2 polymorphs primarily stem from the arrangement of [CeO9] and [KO10] structural units, as evidenced by the dipole moments and the first principles calculations. Our work not only provides new insights into the controlled synthesis of polymorphic materials but also advances the development of tunable birefringent materials for integrated photonic.

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热激相变引发的高稳定可逆双折射开关

操纵双折射晶体的光偏振是光子应用的核心。然而，以无创的方式控制固有的光学各向异性仍然是一个挑战。在这里，我们发现了无机双折射晶体KCe(SO4)2的多态性。P21/c -KCe(SO4)2晶体可通过多晶形可控合成得到。有趣的是，-KCe(SO4)2表现出可逆相变，在此过程中双折射率变化高达50%。该材料具有很高的稳定性，热诱导相变激发的双折射变化在10个周期以上是可逆的，证明了它作为双折射开关的潜力。我们发现KCe(SO4)2多晶的光学各向异性主要源于[CeO9]和[KO10]结构单元的排列，偶极矩和第一性原理计算证明了这一点。我们的工作不仅为多晶材料的受控合成提供了新的见解，而且还推动了可调双折射集成光子材料的发展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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