Enhanced near-infrared optical transmission in zinc germanium phosphide crystals via precise magnesium doping.
Shichao ChengXueyan ZhangXiangran KongTao LiuJingdong YanTetiana PrikhnaYunfei ShangZuotao LeiChunhui YangPublished in: Physical chemistry chemical physics : PCCP (2024)
A zinc germanium phosphorus (ZnGeP 2 ) crystal with a chalcopyrite structure is an efficient frequency converter in the mid-infrared region. However, point defect-induced optical absorption at the pumping wavelength (near infrared region) blocked the further application of ZnGeP 2 . To alleviate the absorption losses caused by point defects, in situ magnesium doping compensation was presented during the ZnGeP 2 bulk crystal growth process via the vertical Bridgman method. Combined with theoretical calculations, the structural distortion of the magnesium-doped ZnGeP 2 crystals in different orientations was illustrated. The thermodynamic and kinetic stability of the magnesium-doped ZnGeP 2 structure were demonstrated. The transmission results indicated the improvement of transmittance within a wavelength range of 1.8-2.4 μm when doped with magnesium, which revealed the powerful ability of the appropriate dopant in optimizing near-infrared optical properties. Thus, the introduction of magnesium is a practical approach to improve the transmittance performance and extend the pumping source wavelengths of ZnGeP 2 crystals.