Nanosized indium selenide saturable absorber for multiple solitons operation in Er3+-doped fiber laser

With the advances in the field of ultrafast photonics occurring so fast, the demand for optical modulation devices with high performance and soliton lasers which can realize the evolution of multiple soliton pulses is gradually increasing. Nevertheless, saturable absorbers (SAs) with appropriate parameters and pulsed fiber lasers which can output abundant mode -locking states still need to be further explored. Due to the special band gap energy values of few-layer indium selenide (InSe) nanosheets, we have prepared a SA based on InSe on a microfiber by optical deposition. In addition, we demonstrate that our prepared SA possesses a modulation depth and saturable absorption intensity about 6.87% and 15.83 MW/cm2, respectively. Then, multiple soliton states are obtained by dispersion management techniques, including regular solitons, and second-order harmonic mode-locking solitons. Meanwhile, we have obtained multi-pulse bound state solitons. We also provide theoretical basis for the existence of these solitons. The results of the experiment show that the InSe has the potential to be an excellent optical modulator because of its excellent saturable absorption properties. This work also is important for improving the understanding and knowledge of InSe and the output performance of fiber lasers.(c) 2023 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement

Automated summary

As the field of ultrafast photonics continues to advance rapidly, there is a growing demand for high-performance optical modulation devices and soliton lasers capable of evolving multiple soliton pulses. In this study, a saturable absorber based on indium selenide (InSe) nanosheets was prepared and shown to possess excellent modulation depth and saturable absorption intensity. By utilizing dispersion management techniques, various soliton states were achieved, including regular solitons and second-order harmonic mode-locking solitons. The experimental results demonstrate the potential of InSe as an excellent optical modulator.