Attosecond transient interferometry

Omer Kneller; Chen Mor; Nikolai D. Klimkin; Noa Yaffe; Michael Krüger; Doron Azoury; Ayelet J. Uzan-Narovlansky; Yotam Federman; Debobrata Rajak; Barry D. Bruner; Olga Smirnova; Serguei Patchkovskii; Yann Mairesse; Misha Ivanov; Nirit Dudovich

doi:10.1038/s41566-024-01556-2

Attosecond transient interferometry

Omer Kneller^*, Chen Mor, Nikolai D. Klimkin, Noa Yaffe, Michael Krüger, Doron Azoury, Ayelet J. Uzan-Narovlansky, Yotam Federman, Debobrata Rajak, Barry D. Bruner, Olga Smirnova, Serguei Patchkovskii, Yann Mairesse, Misha Ivanov, Nirit Dudovich^*

^*Corresponding author for this work

Department of Physics of Complex Systems

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

Attosecond transient absorption resolves the instantaneous response of a quantum system as it interacts with a laser field, by mapping its sub-cycle dynamics onto the absorption spectrum of attosecond pulses. However, the quantum dynamics are imprinted in the amplitude, phase and polarization state of the attosecond pulses. Here we introduce attosecond transient interferometry and measure the transient phase, as we follow its evolution within the optical cycle. We demonstrate how such phase information enables us to decouple the multiple quantum paths induced in a light-driven system, isolating their coherent contribution and retrieving their temporal evolution. Applying attosecond transient interferometry reveals the Stark shift dynamics in helium and retrieves long-term electronic coherences in neon. Finally, we present a vectorial generalization of our scheme, theoretically demonstrating the ability to isolate the underlying anomalous current in light-driven topological materials. Our scheme provides a direct insight into the interplay of light-induced dynamics and topology. Attosecond transient interferometry holds the potential to considerably extend the scope of attosecond metrology, revealing the underlying coherences in light-driven complex systems.

Original language	English
Article number	15734
Pages (from-to)	134-141
Number of pages	9
Journal	Nature Photonics
Volume	19
Issue number	2
Early online date	1 Nov 2024
DOIs	https://doi.org/10.1038/s41566-024-01556-2
Publication status	Published - Feb 2025

Funding

We thank J. Leonard for helpful discussions, Y. Pilas for his technical support and G. Han for his contribution to the mechanical design. N.D. is the incumbent of the Robin Chemers Neustein Professorial Chair. N.D. acknowledges the Minerva Foundation, the Israeli Science Foundation, the Crown Center of Photonics and the European Research Council (ERC) for financial support. M.I. acknowledges support from SFB 1477 ‘Light–matter interaction at interfaces’ (grant no. 441234705). O.S. acknowledges funding from the European Union (ERC, ULISSES, grant no. 101054696). This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement no. 899794. O.K. acknowledges the Azrieli Foundation for the award of an Azrieli Fellowship. D.A. acknowledges financial support from the Zuckerman STEM Leadership Program.

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Atomic and Molecular Physics, and Optics

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10.1038/s41566-024-01556-2Licence: CC BY

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title = "Attosecond transient interferometry",

abstract = "Attosecond transient absorption resolves the instantaneous response of a quantum system as it interacts with a laser field, by mapping its sub-cycle dynamics onto the absorption spectrum of attosecond pulses. However, the quantum dynamics are imprinted in the amplitude, phase and polarization state of the attosecond pulses. Here we introduce attosecond transient interferometry and measure the transient phase, as we follow its evolution within the optical cycle. We demonstrate how such phase information enables us to decouple the multiple quantum paths induced in a light-driven system, isolating their coherent contribution and retrieving their temporal evolution. Applying attosecond transient interferometry reveals the Stark shift dynamics in helium and retrieves long-term electronic coherences in neon. Finally, we present a vectorial generalization of our scheme, theoretically demonstrating the ability to isolate the underlying anomalous current in light-driven topological materials. Our scheme provides a direct insight into the interplay of light-induced dynamics and topology. Attosecond transient interferometry holds the potential to considerably extend the scope of attosecond metrology, revealing the underlying coherences in light-driven complex systems.",

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AU - Krüger, Michael

AU - Azoury, Doron

AU - Uzan-Narovlansky, Ayelet J.

AU - Federman, Yotam

AU - Rajak, Debobrata

AU - Bruner, Barry D.

AU - Smirnova, Olga

AU - Patchkovskii, Serguei

AU - Mairesse, Yann

AU - Ivanov, Misha

AU - Dudovich, Nirit

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N2 - Attosecond transient absorption resolves the instantaneous response of a quantum system as it interacts with a laser field, by mapping its sub-cycle dynamics onto the absorption spectrum of attosecond pulses. However, the quantum dynamics are imprinted in the amplitude, phase and polarization state of the attosecond pulses. Here we introduce attosecond transient interferometry and measure the transient phase, as we follow its evolution within the optical cycle. We demonstrate how such phase information enables us to decouple the multiple quantum paths induced in a light-driven system, isolating their coherent contribution and retrieving their temporal evolution. Applying attosecond transient interferometry reveals the Stark shift dynamics in helium and retrieves long-term electronic coherences in neon. Finally, we present a vectorial generalization of our scheme, theoretically demonstrating the ability to isolate the underlying anomalous current in light-driven topological materials. Our scheme provides a direct insight into the interplay of light-induced dynamics and topology. Attosecond transient interferometry holds the potential to considerably extend the scope of attosecond metrology, revealing the underlying coherences in light-driven complex systems.

AB - Attosecond transient absorption resolves the instantaneous response of a quantum system as it interacts with a laser field, by mapping its sub-cycle dynamics onto the absorption spectrum of attosecond pulses. However, the quantum dynamics are imprinted in the amplitude, phase and polarization state of the attosecond pulses. Here we introduce attosecond transient interferometry and measure the transient phase, as we follow its evolution within the optical cycle. We demonstrate how such phase information enables us to decouple the multiple quantum paths induced in a light-driven system, isolating their coherent contribution and retrieving their temporal evolution. Applying attosecond transient interferometry reveals the Stark shift dynamics in helium and retrieves long-term electronic coherences in neon. Finally, we present a vectorial generalization of our scheme, theoretically demonstrating the ability to isolate the underlying anomalous current in light-driven topological materials. Our scheme provides a direct insight into the interplay of light-induced dynamics and topology. Attosecond transient interferometry holds the potential to considerably extend the scope of attosecond metrology, revealing the underlying coherences in light-driven complex systems.

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Attosecond transient interferometry

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