Incorporating rare-earth cations with moderate electropositivity into iodates for the optimized second-order nonlinear optical performance

Infrared (IR) nonlinear optical (NLO) materials have attracted tremendous interest for civil and military applications, but it remains a great contemporary challenge to develop high-efficiency NLO crystals that possess sufficiently high second-harmonic generation (SHG) efficiencies coupled to wide transparency ranges and high laser damage thresholds. A series of new hydrous rare-earth iodates RE(IO3)(3)center dot(H2O) (RE = Y 1, Eu 2) and La-2(IO3)(6)(H2O) (3) have been synthesized through facile hydrothermal methods. 1 and 2 are isostructural, crystallizing in the polar space group P2(1), while 3 crystallizes in the polar space group Pc. 1-3 feature three-dimensional (3D) frameworks composed of alternately connected corner-shared distorted [REOx] polyhedra (RE = Y, Eu, and La; x = 8, 9) and [IO3](-) groups. Optical studies showed that 1-3 exhibit good NLO properties, including strong SHG intensities (3.0 x (1), 4.5 x (2), and 1.5 x KH2PO4 (3)), large band gaps (4.12 (1), 4.36 (2), and 4.24 eV (3), with 2 possessing the largest band gap among the known SHG-active rare-earth-based iodates, high laser damage thresholds (LDT) (53 x (1), 43 x (2), and 44 x AgGaS2 (3)), and wide transparency ranges (ca. 3.0-11.3 mu m) in the mid-IR region covering two critical IR transparency windows; 1-3 are therefore potential candidate NLO materials. Density functional theory calculations on 1-3 confirm that their strong SHG responses and large band gaps are mainly derived from the synergistic effect of [IO3](-) groups and rare-earth oxide polyhedra [REOx] in their 3D frameworks. We conclude that the introduction of rare-earth cations with moderate electropositivity into iodates may optimize the balance between SHG efficiency and optical band gaps, the key requirement for high-performance NLO materials for practical applications.