Nonlinear optical properties and broadband ultrafast photonics application of 2D-zirconium tritelluride (ZrTe3)

Two-dimensional (2D) transition metal chalcogenides (TMCs) have lately attracted broad interest in advanced photonics field due to their tunable bandgap, high broadband absorption, and excellent nonlinear optical (NLO) performances. Among other TMCs, group-IV transition metal trichalcogenides (TMTs) are rarely investigated for the NLO applications. Zirconium tritelluride (ZrTe3) is a kind of group-IV TMTs that shows metallic behavior among TMTs materials. While several electrical properties of ZrTe3 have been studied recently, the research community is longing to explore NLO features of ZrTe3. Herein, by using open aperture Z-scan method, the NLO properties of ZrTe3-nanosheets are investigated. The admirable NLO characteristics of ZrTe3 are realized from the obtained highest nonlinear absorption coefficient value of -82.1 x 10(3) in 1 mu m and -13.05 x 10(3) cm/GW in 1.5 mu m. Moreover, broadband fiber optics ZrTe3-based saturable absorbers (SAs) are prepared for the first time by depositing 2D-ZrTe3 nanosheets on a side-polished fiber. Following integration of these ZrTe3-SAs into three distinct rare earth-doped fiber laser cavities, stable mode-locking pulses with pulse widths of 323 ps (1 mu m), 751 fs (1.5 mu m), and 1.2 ps (2 mu m) are obtained, respectively. These findings indicate that the ZrTe3 can facilitate the exploration of 2D materials in nonlinear optics and ultrafast photonics applications.

Automated summary

Recently, two-dimensional transition metal chalcogenides (TMCs) have attracted attention in advanced photonics due to their tunable bandgap, high broadband absorption, and excellent nonlinear optical (NLO) performance. Among TMCs, group-IV transition metal trichalcogenides (TMTs) have been rarely studied for NLO applications. This study investigates the NLO properties of ZrTe3-nanosheets and prepares ZrTe3-based saturable absorbers (SAs) for the first time, enabling stable mode-locking pulses in different fiber laser cavities.