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Ultra‐High Optical Anisotropy with UV Transmission Achieved by Rational Arrangement of Extended π‐Conjugated Groups

Danyang Dou, Chao Wei, Bingbing Zhang, Daqing Yang, Ying Wang

2025Angewandte Chemie International Edition34 citationsDOIOpen Access PDF

Abstract

Abstract Birefringent material serves as a cornerstone in photonic applications, including optical communications, polarization control, and laser technologies. The development of birefringent materials with large birefringence (Δ n > 0.3) and short ultraviolet (UV) cut‐off edge ( λ cut‐off edge < 400 nm) remains a significant challenge. Here, we demonstrate that properly aligned expanded π‐conjugated groups provide a solution to balance the birefringence and UV transmittance. We report a new birefringent material, Li 3 (C 9 N 13 )·6H 2 O ( LCN ), in which the Li atoms and water molecules act as linkers to connect the birefringence‐active group [C 9 N 13 ]. This crystal material exhibits a giant optical anisotropy (Δ n exp = 1.031 @ 546 nm), which is one of the highest among bulk crystal materials known to date. In addition, LCN shows a band gap of 3.62 eV, indicating its applicability in the UV optical range. Owing to favorable Li cation linkers and hydrogen bonding, the [C 9 N 13 ] groups achieve a perfectly coplanar arrangement, thereby maximizing the optical anisotropy. This work offers a novel strategy for the rational design of advanced birefringent materials.

Topics & Concepts

BirefringenceMaterials scienceAnisotropyOptoelectronicsUltravioletBand gapTransmittancePolarization (electrochemistry)Photonic crystalOpticsPhotonicsChemistryPhysicsPhysical chemistrySilicone and Siloxane ChemistryPerovskite Materials and ApplicationsCrystal Structures and Properties
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