Rational Design of a Deep-Ultraviolet Nonlinear Optical Crystal
Haonan Liu, Hongping Wu, Zhanggui Hu, Jiyang Wang, Yicheng Wu, Hongwei Yu
Abstract
Rational structural design of inorganic materials remains a significant challenge in materials science, particularly for deep-ultraviolet (DUV) nonlinear optical (NLO) crystals. Herein, a new DUV-transparent NLO borate, CsSrB 3 O 6 (CSBO), has been successfully predicted and synthesized by the cation regulation from Cs 2 KY(B 3 O 6 ) 2 (CKYBO). The structural stability of CSBO was confirmed by first-principles phonon vibration calculations, and it was eventually synthesized via a high-temperature solid-state reaction. The substitution of K + /Y 3+ cations with Sr 2+ cations eliminates the disorder and significantly reduces the thermal expansion anisotropy (CKYBO: 9.32, CSBO: 1.95), which effectively protects the crystals from cracking during crystal growth. Furthermore, CSBO successfully achieved the ordered design of B 3 O 6 functional groups, and this structural feature enables it to display well-balanced functional performance, including a strong second-harmonic generation response (5.0 × KH 2 PO 4 ), a short UV absorption edge (<190 nm), and moderate birefringence (0.075@1064 nm). All of these results demonstrate that CSBO is a promising DUV NLO material, and this study establishes an effective strategy for developing high-performance NLO crystals through synergistic computational-experimental approaches.