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Femtosecond Fieldoscopy for label-free sensing

ORAL · Invited

Abstract

Field-resolved detection at near-petahertz frequencies [1] offers exceptional sensitivity, bandwidth, and dynamic range, enabling attosecond temporal resolution and sub-diffraction spatial precision. A novel approach, termed Femtosecond Fieldoscopy, leverages ultrashort excitation laser pulses to impulsively excite the in-resonance molecular composition of a sample at near-petahertz frequencies. This interaction induces vibrational coherence at the trailing edge of the pulses, which subsequently decays at a rate determined by vibrational dephasing time.

The transmitted electric field encodes information about the ultrashort excitation pulse, the sample’s delayed response over several picoseconds, and a prolonged atmospheric response lasting hundreds of nanoseconds. By applying field-resolved detection in the time domain and performing Fourier analysis of the decaying molecular response, the technique achieves unprecedented spectroscopic sensitivity and dynamic range. This is made possible by temporally gating the molecular response from the excitation pulse.

Advancements in ytterbium laser technology [2-6] have enabled Femtosecond Fieldoscopy to resolve overtone, Raman, and combination bands in liquid samples [7-9]. Additionally, various approaches have accelerated the technique for real-time sampling [10-12] and expanded its capabilities to non-perturbative, label-free imaging [13, 14].

In this talk, I will provide an overview of recent breakthroughs in this field demonstrated by my group. If time permits, I will conclude with a brief discussion of our ongoing work on developing solar lasers and their potential applications in space exploration [15].

Publication: [1] Andreas Herbst, Kilian Scheffter, MM Bidhendi, M Kieker, Anchit Srivastava, and Hanieh Fattahi. Recent advances in petahertz electric field sampling. Journal of Physics B: Atomic, Molecular and Optical Physics, 55(17):172001, 2022.<br>[2] Hanieh Fattahi, Helena G Barros, Martin Gorjan, Thomas Nubbemeyer, Bidoor Alsaif, Catherine Y Teisset, Marcel Schultze, Stephan<br>Prinz, Matthias Haefner, Moritz Ueffing, et al. Third-generation femtosecond technology. Optica, 1(1):45–63, 2014.<br>[3] A Alismail, H Wang, G Barbiero, N Altwaijry, SA Hussain, V Pervak, W Schweinberger, AM Azzeer, F Krausz, and H Fattahi. Multi-<br>octave, cep-stable source for high-energy field synthesis sci, 2020.<br>[4] Tatiana Amotchkina, Hanieh Fattahi, Yurij A Pervak, Michael Trubetskov, and Vladimir Pervak. Broadband beamsplitter for high<br>intensity laser applications in the infra-red spectral range. Optics express, 24(15):16752–16759, 2016.<br>[5] Hanieh Fattahi. Sub-cycle light transients for attosecond, x-ray, four-dimensional imaging. Contemporary Physics, 57(4):580–595, 2016.<br>[6] Theresa Buberl, Ayman Alismail, Haochuan Wang, Nicholas Karpowicz, and Hanieh Fattahi. Self-compressed, spectral broadening of a yb:Yag thin-disk amplifier. Optics express, 24(10):10286–10294, 2016.<br>[7] Anchit Srivastava, Andreas Herbst, Mahdi M Bidhendi, Max Kieker, Francesco Tani, and Hanieh Fattahi. Near-petahertz fieldoscopy of liquid. Nature Photonics, pages 1–7, 2024.<br>[8] K Scheffter, A Srivastava, A Herbst, S Jun, and H Fattahi. Field-resolved stimulated raman spectroscopy. In 2024 IEEE Photonics<br>Conference (IPC), pages 1–2. IEEE, 2024.<br>[9] A Srivastava, A Herbst, and H Fattahi. Field-resolved, far-field characterization of air bubbles in liquid water. In 2024 IEEE Photonics<br>Conference (IPC), pages 1–2. IEEE, 2024.<br>[10] S Gommel, M Lippl, K Scheffter, A Srivastava, A Herbst, NY Joly, and H Fattahi. Towards field-resolved photonic time stretch at near-petahertz frequencies. In 2024 IEEE Photonics Conference (IPC), pages 1–2. IEEE, 2024.<br>[11] Kilian Scheffter, Jonathan Will, Claudius Riek, Herve Jousselin, S´ebastien Coudreau, Nicolas Forget, and Hanieh Fattahi. Compressed sensing of field-resolved molecular fingerprints beyond the nyquist frequency. Ultrafast Science, 4:0062, 2024.<br>[12] Anni Li, Mehran Bahri, Robert M Gray, Seowon Choi, Sajjad Hoseinkhani, Anchit Srivastava, Alireza Marandi, and Hanieh Fattahi. 0.7 mw yb: Yag pumped degenerate optical parametric oscillator at 2.06 μm. APL Photonics, 9(10), 2024.<br>[13] Soyeon Jun, Andreas Herbst, Kilian Scheffter, Nora John, Julia Kolb, Daniel Wehner, and Hanieh Fattahi. Nonlinear dynamics of<br>femtosecond laser interaction with the central nervous system in zebrafish. Communications Physics, 7(1):161, 2024.<br>[14] A Herbst, A Srivastava, K Scheffter, S Jun, N Petrini, A Rubino, I Kriegel, and H Fattahi. Label-free hyperspectral microscopy with<br>attosecond precision. In 2024 IEEE Photonics Conference (IPC), pages 1–2. IEEE, 2024.<br>[15] Michael Küblböck, Jonathan Will, and Hanieh Fattahi. Solar lasers: Why not? APL Photonics,9(5):050903, 05 2024.

Presenters

  • Hanieh Fattahi

    Max Plank Institute for the Science of Light

Authors

  • Hanieh Fattahi

    Max Plank Institute for the Science of Light