Relativistic single-cycle tunable infrared pulses generated from a tailored plasma density structure

Zan Nie; Chih Hao Pai; Jianfei Hua; Chaojie Zhang; Yipeng Wu; Yang Wan; Fei Li; Jie Zhang; Zhi Cheng; Qianqian Su; Shuang Liu; Yue Ma; Xiaonan Ning; Yunxiao He; Wei Lu; Hsu Hsin Chu; Jyhpyng Wang; Warren B. Mori; Chan Joshi

doi:10.1038/s41566-018-0190-8

Relativistic single-cycle tunable infrared pulses generated from a tailored plasma density structure

Zan Nie, Chih Hao Pai, Jianfei Hua, Chaojie Zhang, Yipeng Wu, Yang Wan, Fei Li, Jie Zhang, Zhi Cheng, Qianqian Su, Shuang Liu, Yue Ma, Xiaonan Ning, Yunxiao He, Wei Lu, Hsu Hsin Chu, Jyhpyng Wang, Warren B. Mori, Chan Joshi

研究成果: 雜誌貢獻 › 期刊論文 › 同行評審

66 引文斯高帕斯（Scopus）

摘要

The availability of intense, ultrashort coherent radiation sources in the infrared region of the spectrum is enabling the generation of attosecond X-ray pulses via high-harmonic generation, pump–probe experiments in the ‘molecular fingerprint’ region and opening up the area of relativistic infrared nonlinear optics of plasmas. These applications would benefit from multi-millijoule single-cycle pulses in the mid- to long-wavelength infrared region. Here, we present a new scheme capable of producing tunable relativistically intense, single-cycle infrared pulses from 5 to 14 μm with a 1.7% conversion efficiency based on a photon frequency downshifting scheme that uses a tailored plasma density structure. The carrier-envelope phase of the long-wavelength infrared pulse is locked to that of the drive laser to within a few per cent. Such a versatile tunable infrared source may meet the demands of many cutting-edge applications in strong-field physics and greatly promote their development.

原文	???core.languages.en_GB???
頁（從 - 到）	489-494
頁數	6
期刊	Nature Photonics
卷	12
發行號	8
DOIs	https://doi.org/10.1038/s41566-018-0190-8
出版狀態	已出版 - 1 8月 2018

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Nie, Z., Pai, C. H., Hua, J., Zhang, C., Wu, Y., Wan, Y., Li, F., Zhang, J., Cheng, Z., Su, Q., Liu, S., Ma, Y., Ning, X., He, Y., Lu, W., Chu, H. H., Wang, J., Mori, W. B., & Joshi, C. (2018). Relativistic single-cycle tunable infrared pulses generated from a tailored plasma density structure. Nature Photonics, 12(8), 489-494. https://doi.org/10.1038/s41566-018-0190-8

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abstract = "The availability of intense, ultrashort coherent radiation sources in the infrared region of the spectrum is enabling the generation of attosecond X-ray pulses via high-harmonic generation, pump–probe experiments in the {\textquoteleft}molecular fingerprint{\textquoteright} region and opening up the area of relativistic infrared nonlinear optics of plasmas. These applications would benefit from multi-millijoule single-cycle pulses in the mid- to long-wavelength infrared region. Here, we present a new scheme capable of producing tunable relativistically intense, single-cycle infrared pulses from 5 to 14 μm with a 1.7% conversion efficiency based on a photon frequency downshifting scheme that uses a tailored plasma density structure. The carrier-envelope phase of the long-wavelength infrared pulse is locked to that of the drive laser to within a few per cent. Such a versatile tunable infrared source may meet the demands of many cutting-edge applications in strong-field physics and greatly promote their development.",

author = "Zan Nie and Pai, {Chih Hao} and Jianfei Hua and Chaojie Zhang and Yipeng Wu and Yang Wan and Fei Li and Jie Zhang and Zhi Cheng and Qianqian Su and Shuang Liu and Yue Ma and Xiaonan Ning and Yunxiao He and Wei Lu and Chu, {Hsu Hsin} and Jyhpyng Wang and Mori, {Warren B.} and Chan Joshi",

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AU - Wan, Yang

AU - Li, Fei

AU - Zhang, Jie

AU - Cheng, Zhi

AU - Su, Qianqian

AU - Liu, Shuang

AU - Ma, Yue

AU - Ning, Xiaonan

AU - He, Yunxiao

AU - Lu, Wei

AU - Chu, Hsu Hsin

AU - Wang, Jyhpyng

AU - Mori, Warren B.

AU - Joshi, Chan

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N2 - The availability of intense, ultrashort coherent radiation sources in the infrared region of the spectrum is enabling the generation of attosecond X-ray pulses via high-harmonic generation, pump–probe experiments in the ‘molecular fingerprint’ region and opening up the area of relativistic infrared nonlinear optics of plasmas. These applications would benefit from multi-millijoule single-cycle pulses in the mid- to long-wavelength infrared region. Here, we present a new scheme capable of producing tunable relativistically intense, single-cycle infrared pulses from 5 to 14 μm with a 1.7% conversion efficiency based on a photon frequency downshifting scheme that uses a tailored plasma density structure. The carrier-envelope phase of the long-wavelength infrared pulse is locked to that of the drive laser to within a few per cent. Such a versatile tunable infrared source may meet the demands of many cutting-edge applications in strong-field physics and greatly promote their development.

AB - The availability of intense, ultrashort coherent radiation sources in the infrared region of the spectrum is enabling the generation of attosecond X-ray pulses via high-harmonic generation, pump–probe experiments in the ‘molecular fingerprint’ region and opening up the area of relativistic infrared nonlinear optics of plasmas. These applications would benefit from multi-millijoule single-cycle pulses in the mid- to long-wavelength infrared region. Here, we present a new scheme capable of producing tunable relativistically intense, single-cycle infrared pulses from 5 to 14 μm with a 1.7% conversion efficiency based on a photon frequency downshifting scheme that uses a tailored plasma density structure. The carrier-envelope phase of the long-wavelength infrared pulse is locked to that of the drive laser to within a few per cent. Such a versatile tunable infrared source may meet the demands of many cutting-edge applications in strong-field physics and greatly promote their development.

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Relativistic single-cycle tunable infrared pulses generated from a tailored plasma density structure

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