Bi4Br4-based saturable absorber with robustness at high power for ultrafast photonic device

Wenjun Liu; Xiaolu Xiong; Mengli Liu; Xiaowei Xing; Hailong Chen; Han Ye; Junfeng Han; Zhiyi Wei

doi:10.1063/5.0077148

Bi₄Br₄-based saturable absorber with robustness at high power for ultrafast photonic device

Wenjun Liu, Xiaolu Xiong, Mengli Liu, Xiaowei Xing, Hailong Chen, Han Ye, Junfeng Han^*, Zhiyi Wei^*

^*Corresponding author for this work

School of Physics

Research output: Contribution to journal › Article › peer-review

51 Citations (Scopus)

Abstract

Saturable absorption may be induced at critical pumping power by nonlinear optical effects of nanomaterials, thereby making it possible to generate a high-power ultrafast laser. Recently, Bi4Br4 is theoretically predicted to be a member of topological insulators and is expected to be a promising candidate for saturable absorbers (SAs). We show here that Bi4Br4 features a large modulation depth of 42.3%. The Bi4Br4-based SA enables mode-locking operation at the near-infrared range, as demonstrated here by a 1.5 μm fiber laser with a signal-to-noise ratio (SNR) of 90 dB and a pulse duration of 172 fs. Moreover, the robustness of the Bi4Br4-based SA at relatively high power is of particular interest, which can be proved by a laser's stable operation state. The strong optical nonlinearity and robustness provided by Bi4Br4 may arouse a growing upsurge in the innovation of high-power ultrafast photonic devices and further development of photon applications.

Original language	English
Article number	053108
Journal	Applied Physics Letters
Volume	120
Issue number	5
DOIs	https://doi.org/10.1063/5.0077148
Publication status	Published - 31 Jan 2022

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title = "Bi4Br4-based saturable absorber with robustness at high power for ultrafast photonic device",

abstract = "Saturable absorption may be induced at critical pumping power by nonlinear optical effects of nanomaterials, thereby making it possible to generate a high-power ultrafast laser. Recently, Bi4Br4 is theoretically predicted to be a member of topological insulators and is expected to be a promising candidate for saturable absorbers (SAs). We show here that Bi4Br4 features a large modulation depth of 42.3%. The Bi4Br4-based SA enables mode-locking operation at the near-infrared range, as demonstrated here by a 1.5 μm fiber laser with a signal-to-noise ratio (SNR) of 90 dB and a pulse duration of 172 fs. Moreover, the robustness of the Bi4Br4-based SA at relatively high power is of particular interest, which can be proved by a laser's stable operation state. The strong optical nonlinearity and robustness provided by Bi4Br4 may arouse a growing upsurge in the innovation of high-power ultrafast photonic devices and further development of photon applications.",

author = "Wenjun Liu and Xiaolu Xiong and Mengli Liu and Xiaowei Xing and Hailong Chen and Han Ye and Junfeng Han and Zhiyi Wei",

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AU - Liu, Wenjun

AU - Xiong, Xiaolu

AU - Liu, Mengli

AU - Xing, Xiaowei

AU - Chen, Hailong

AU - Ye, Han

AU - Han, Junfeng

AU - Wei, Zhiyi

PY - 2022/1/31

Y1 - 2022/1/31

N2 - Saturable absorption may be induced at critical pumping power by nonlinear optical effects of nanomaterials, thereby making it possible to generate a high-power ultrafast laser. Recently, Bi4Br4 is theoretically predicted to be a member of topological insulators and is expected to be a promising candidate for saturable absorbers (SAs). We show here that Bi4Br4 features a large modulation depth of 42.3%. The Bi4Br4-based SA enables mode-locking operation at the near-infrared range, as demonstrated here by a 1.5 μm fiber laser with a signal-to-noise ratio (SNR) of 90 dB and a pulse duration of 172 fs. Moreover, the robustness of the Bi4Br4-based SA at relatively high power is of particular interest, which can be proved by a laser's stable operation state. The strong optical nonlinearity and robustness provided by Bi4Br4 may arouse a growing upsurge in the innovation of high-power ultrafast photonic devices and further development of photon applications.

AB - Saturable absorption may be induced at critical pumping power by nonlinear optical effects of nanomaterials, thereby making it possible to generate a high-power ultrafast laser. Recently, Bi4Br4 is theoretically predicted to be a member of topological insulators and is expected to be a promising candidate for saturable absorbers (SAs). We show here that Bi4Br4 features a large modulation depth of 42.3%. The Bi4Br4-based SA enables mode-locking operation at the near-infrared range, as demonstrated here by a 1.5 μm fiber laser with a signal-to-noise ratio (SNR) of 90 dB and a pulse duration of 172 fs. Moreover, the robustness of the Bi4Br4-based SA at relatively high power is of particular interest, which can be proved by a laser's stable operation state. The strong optical nonlinearity and robustness provided by Bi4Br4 may arouse a growing upsurge in the innovation of high-power ultrafast photonic devices and further development of photon applications.

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Bi₄Br₄-based saturable absorber with robustness at high power for ultrafast photonic device

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