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Main Authors: Wang, Yingwei, Zhou, Li, Long, Quan, Li, Xin, Chang, Haolin, Li, Ning, Wang, Yiduo, Zhang, Bei, Chen, Zhihui, Yang, Zhongjian, Xiao, Si, Zhao, Chujun, Wen, Shuangchun, He, Jun
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2508.17617
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author Wang, Yingwei
Zhou, Li
Long, Quan
Li, Xin
Chang, Haolin
Li, Ning
Wang, Yiduo
Zhang, Bei
Chen, Zhihui
Yang, Zhongjian
Xiao, Si
Zhao, Chujun
Wen, Shuangchun
He, Jun
author_facet Wang, Yingwei
Zhou, Li
Long, Quan
Li, Xin
Chang, Haolin
Li, Ning
Wang, Yiduo
Zhang, Bei
Chen, Zhihui
Yang, Zhongjian
Xiao, Si
Zhao, Chujun
Wen, Shuangchun
He, Jun
contents Plasmon-driven ultrafast nonlinearities hold promise for advanced photonics but remain challenging to harness in two-dimensional materials at telecommunication wavelengths. Here, we demonstrate few-layer V2C MXene as a high-performance saturable absorber by leveraging its tailored surface plasmon resonance. Combining transient absorption spectroscopy and first-principles calculations, we unveil a plasmon-driven relaxation mechanism dominated by interfacial high-energy hot electron generation (~100 fs), enabling giant ultrafast nonlinearities. Crucially, at the communication band (1550 nm), V2C exhibits a high saturable absorption coefficient of -1.35 cm/GW. Integrating this into an erbium-doped fiber laser, we generate mode-locked pulses with a duration of 486 fs at 1569 nm, a 39.51 MHz repetition rate, and exceptional stability (92 dB SNR). This work establishes plasmonic MXenes as a paradigm for tailored ultrafast photonic devices.
format Preprint
id arxiv_https___arxiv_org_abs_2508_17617
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Plasmon-driven Ultrafast and Highly Efficient Saturable Absorption for Ultrashort Pulse Generation Based on 2D V2C
Wang, Yingwei
Zhou, Li
Long, Quan
Li, Xin
Chang, Haolin
Li, Ning
Wang, Yiduo
Zhang, Bei
Chen, Zhihui
Yang, Zhongjian
Xiao, Si
Zhao, Chujun
Wen, Shuangchun
He, Jun
Optics
Applied Physics
Plasmon-driven ultrafast nonlinearities hold promise for advanced photonics but remain challenging to harness in two-dimensional materials at telecommunication wavelengths. Here, we demonstrate few-layer V2C MXene as a high-performance saturable absorber by leveraging its tailored surface plasmon resonance. Combining transient absorption spectroscopy and first-principles calculations, we unveil a plasmon-driven relaxation mechanism dominated by interfacial high-energy hot electron generation (~100 fs), enabling giant ultrafast nonlinearities. Crucially, at the communication band (1550 nm), V2C exhibits a high saturable absorption coefficient of -1.35 cm/GW. Integrating this into an erbium-doped fiber laser, we generate mode-locked pulses with a duration of 486 fs at 1569 nm, a 39.51 MHz repetition rate, and exceptional stability (92 dB SNR). This work establishes plasmonic MXenes as a paradigm for tailored ultrafast photonic devices.
title Plasmon-driven Ultrafast and Highly Efficient Saturable Absorption for Ultrashort Pulse Generation Based on 2D V2C
topic Optics
Applied Physics
url https://arxiv.org/abs/2508.17617