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A<sub>3</sub>BBi(P<sub>2</sub>O<sub>7</sub>)<sub>2</sub> (A = Rb, Cs; B = Pb, Ba): Isovalent Cation Substitution to Sustain Large Second-Harmonic Generation Responses

Lu Qi, Zhaohui Chen, Xuerui Shi, Xiaodong Zhang, Qun Jing, Na Li, Zhongqi Jiang, Bingbing Zhang, Ming‐Hsien Lee

2020Chemistry of Materials102 citationsDOI

Abstract

Exploring novel photoelectric functional materials via chemical substitution-oriented design is an effective strategy, which can be expanded to the discovery of high-performance UV nonlinear optical (NLO) materials. Two new NLO pyrophosphates, Rb3BaBi(P2O7)2 (I) and Cs3BaBi(P2O7)2 (II), are rationally developed by a cation substitution technique based on A3PbBi(P2O7)2 (A = Rb and Cs), of which I inherits the large second-harmonic generation (SHG) response (exptl 2.5 × KDP; calcd 2.9 × KDP) and moderate birefringence (0.025@1064 nm) accompanied by a broadened UV transparent region. Compounds I and II are isomeric and exhibit different Ba–P–O frameworks. Especially, I possesses a large SHG effect benefiting from the favorable pentagonal-net topological structure. Detailed theory calculations elucidate the origin of the linear and nonlinear optical properties of the compounds. The insights obtained from the atomic-level module adjustment involving lone-pair-active optical anisotropy are useful for designing more efficient UV NLO materials.

Topics & Concepts

Second-harmonic generationSubstitution (logic)Nonlinear opticalAnisotropyBirefringenceMaterials sciencePhotoelectric effectNonlinear opticsLone pairOptical materialsCrystallographyOptoelectronicsChemistryNonlinear systemMoleculeOpticsPhysicsOrganic chemistryComputer scienceLaserProgramming languageQuantum mechanicsCrystal Structures and PropertiesSolid-state spectroscopy and crystallographyCrystal structures of chemical compounds