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    Journals >Acta Photonica Sinica >Volume 50 >Issue 8 >Page 0850204 > Article
    • Acta Photonica Sinica
    • Vol. 50, Issue 8, 0850204 (2021)
    Probing Intrinsic Attosecond Electron Dynamics and Interactions in Condensed Matters (Invited)
    Zhensheng TAO
    Author Affiliations
  • State Key Laboratory of Surface Physics, Department of Physics, Fudan University, Shanghai200438, China
    • show less
    DOI: 10.3788/gzxb20215008.0850204 Cite this Article
    Zhensheng TAO. Probing Intrinsic Attosecond Electron Dynamics and Interactions in Condensed Matters (Invited)[J]. Acta Photonica Sinica, 2021, 50(8): 0850204 Copy Citation Text show less
    Illustration of the three-step model of HHG
    Fig. 1. Illustration of the three-step model of HHG
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    Illustration of the characteristic HHG spectrum with discrete orders and the temporal structure of attosecond pulse trains[23]
    Fig. 2. Illustration of the characteristic HHG spectrum with discrete orders and the temporal structure of attosecond pulse trains23
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    Illustration of the quantum-path interference in RABBITT measurements[23]
    Fig. 3. Illustration of the quantum-path interference in RABBITT measurements23
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    The experimental setup of RABBITT[23]
    Fig. 4. The experimental setup of RABBITT23
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    The spectral and temporal profiles of 43-as isolated attosecond pulses[40]
    Fig. 5. The spectral and temporal profiles of 43-as isolated attosecond pulses40
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    The experimental setup for isolated-attosecond-pulse generation and attosecond streaking[40]
    Fig. 6. The experimental setup for isolated-attosecond-pulse generation and attosecond streaking40
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    Comparison between the attosecond streaking camera and RABBITT[69]
    Fig. 7. Comparison between the attosecond streaking camera and RABBITT69
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    Simulated photoelectron spectra (color plots) of RABBITT and attosecond streaking camera, corresponding to four different EUV excitation spectra[69]
    Fig. 8. Simulated photoelectron spectra (color plots) of RABBITT and attosecond streaking camera, corresponding to four different EUV excitation spectra69
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    The attosecond photoemission time delay between the W 4f core-level and conduction-band electrons measured by attosecond streaking camera[71]
    Fig. 9. The attosecond photoemission time delay between the W 4f core-level and conduction-band electrons measured by attosecond streaking camera71
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    The experimental setup of atto-ARPES
    Fig. 10. The experimental setup of atto-ARPES
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    The photoemission time delay of the conduction electrons of Ni(111) measured by RABBITT[30]
    Fig. 11. The photoemission time delay of the conduction electrons of Ni(111) measured by RABBITT30
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    The angle-dependence of photoemission time delay from the Ni(111) surface[30]
    Fig. 12. The angle-dependence of photoemission time delay from the Ni(111) surface30
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    The angle-dependence of photoemission time delay from the Cu(111) surface[84]
    Fig. 13. The angle-dependence of photoemission time delay from the Cu(111) surface84
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    Comparison of attosecond photoemission time delay of Cu(111) and Ni(111)[27]
    Fig. 14. Comparison of attosecond photoemission time delay of Cu(111) and Ni(111)27
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    Broadband lifetime of photo-excited electrons in Cu and Ni as a function of photon energy[27]
    Fig. 15. Broadband lifetime of photo-excited electrons in Cu and Ni as a function of photon energy27
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    Abstract
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    Zhensheng TAO. Probing Intrinsic Attosecond Electron Dynamics and Interactions in Condensed Matters (Invited)[J]. Acta Photonica Sinica, 2021, 50(8): 0850204
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