Attosecond X-Ray Core-Level Chronoscopy of Aromatic Molecules

Jia Bao Ji; Zhaoheng Guo; Taran Driver; Cynthia S. Trevisan; David Cesar; Xinxin Cheng; Joseph Duris; Paris L. Franz; James Glownia; Xiaochun Gong; Daniel Hammerland; Meng Han; Saijoscha Heck; Matthias Hoffmann; Andrei Kamalov; Kirk A. Larsen; Xiang Li; Ming Fu Lin; Yuchen Liu; C. William McCurdy; Razib Obaid; Jordan T. O'Neal; Thomas N. Rescigno; River R. Robles; Nicholas Sudar; Peter Walter; Anna L. Wang; Jun Wang; Thomas J.A. Wolf; Zhen Zhang; Kiyoshi Ueda; Robert R. Lucchese; Agostino Marinelli; James P. Cryan; Hans Jakob Wörner

doi:10.1103/dp5w-qxqc

Attosecond X-Ray Core-Level Chronoscopy of Aromatic Molecules

Jia Bao Ji
, Zhaoheng Guo
, Taran Driver
, Cynthia S. Trevisan
, David Cesar
, Xinxin Cheng
, Joseph Duris
, Paris L. Franz
, James Glownia
, Xiaochun Gong
, Daniel Hammerland
, Meng Han
, Saijoscha Heck
, Matthias Hoffmann
, Andrei Kamalov
, Kirk A. Larsen
, Xiang Li
, Ming Fu Lin
, Yuchen Liu
, C. William McCurdy

Razib Obaid, Jordan T. O'Neal, Thomas N. Rescigno, River R. Robles, Nicholas Sudar, Peter Walter, Anna L. Wang, Jun Wang, Thomas J.A. Wolf, Zhen Zhang, Kiyoshi Ueda, Robert R. Lucchese^*, Agostino Marinelli^*, James P. Cryan^*, Hans Jakob Wörner^*

^*Corresponding author for this work

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

Abstract

Attosecond photoemission or photoionization delays are a unique probe of the structure and the electronic dynamics of matter. However, the spectral congestion of valence photoelectron spectra sets fundamental limits to the complexity of systems that can be studied, and the delocalization of valence electron wave functions blurs the spatial origin of the photoelectron wave packet. Using attosecond x-ray pulses from LCLS, we demonstrate the key advantages of measuring core-level delays: The photoelectron spectra remain atomlike, the measurements become element specific, and the observed scattering dynamics originate from a pointlike source when multicenter interference effects are negligible. We exploit these unique features to reveal the effects of changing functional groups (C-H vs N) and symmetry on attosecond scattering dynamics by measuring and calculating the photoionization delays between N-1s and C-1s core shells of a series of aromatic azabenzene molecules. Remarkably, the delays increase with the number of nitrogen atoms in the molecule and reveal multiple resonances. We identify two previously unknown mechanisms regulating the associated attosecond dynamics, namely the enhanced confinement of the trapped wave function with the replacement of C-H groups by N atoms and the decrease of the coupling strength among the photoemitted partial waves with increasing symmetry. This study demonstrates the unique opportunities opened by measurements of core-level photoionization delays for unraveling attosecond electron dynamics in complex matter.

Original language	English
Article number	041031
Journal	Physical Review X
Volume	15
Issue number	4
DOIs	https://doi.org/10.1103/dp5w-qxqc
State	Published - Oct 2025
Externally published	Yes

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10.1103/dp5w-qxqc

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Ji, J. B., Guo, Z., Driver, T., Trevisan, C. S., Cesar, D., Cheng, X., Duris, J., Franz, P. L., Glownia, J., Gong, X., Hammerland, D., Han, M., Heck, S., Hoffmann, M., Kamalov, A., Larsen, K. A., Li, X., Lin, M. F., Liu, Y., ... Wörner, H. J. (2025). Attosecond X-Ray Core-Level Chronoscopy of Aromatic Molecules. Physical Review X, 15(4), Article 041031. https://doi.org/10.1103/dp5w-qxqc

@article{9f53159fba2643afaa23ee1145ea9068,

title = "Attosecond X-Ray Core-Level Chronoscopy of Aromatic Molecules",

abstract = "Attosecond photoemission or photoionization delays are a unique probe of the structure and the electronic dynamics of matter. However, the spectral congestion of valence photoelectron spectra sets fundamental limits to the complexity of systems that can be studied, and the delocalization of valence electron wave functions blurs the spatial origin of the photoelectron wave packet. Using attosecond x-ray pulses from LCLS, we demonstrate the key advantages of measuring core-level delays: The photoelectron spectra remain atomlike, the measurements become element specific, and the observed scattering dynamics originate from a pointlike source when multicenter interference effects are negligible. We exploit these unique features to reveal the effects of changing functional groups (C-H vs N) and symmetry on attosecond scattering dynamics by measuring and calculating the photoionization delays between N-1s and C-1s core shells of a series of aromatic azabenzene molecules. Remarkably, the delays increase with the number of nitrogen atoms in the molecule and reveal multiple resonances. We identify two previously unknown mechanisms regulating the associated attosecond dynamics, namely the enhanced confinement of the trapped wave function with the replacement of C-H groups by N atoms and the decrease of the coupling strength among the photoemitted partial waves with increasing symmetry. This study demonstrates the unique opportunities opened by measurements of core-level photoionization delays for unraveling attosecond electron dynamics in complex matter.",

author = "Ji, \{Jia Bao\} and Zhaoheng Guo and Taran Driver and Trevisan, \{Cynthia S.\} and David Cesar and Xinxin Cheng and Joseph Duris and Franz, \{Paris L.\} and James Glownia and Xiaochun Gong and Daniel Hammerland and Meng Han and Saijoscha Heck and Matthias Hoffmann and Andrei Kamalov and Larsen, \{Kirk A.\} and Xiang Li and Lin, \{Ming Fu\} and Yuchen Liu and McCurdy, \{C. William\} and Razib Obaid and O'Neal, \{Jordan T.\} and Rescigno, \{Thomas N.\} and Robles, \{River R.\} and Nicholas Sudar and Peter Walter and Wang, \{Anna L.\} and Jun Wang and Wolf, \{Thomas J.A.\} and Zhen Zhang and Kiyoshi Ueda and Lucchese, \{Robert R.\} and Agostino Marinelli and Cryan, \{James P.\} and W{\"o}rner, \{Hans Jakob\}",

note = "Publisher Copyright: {\textcopyright} 2025 authors. Published by the American Physical Society. Published by the American Physical Society under the terms of the {"}https://creativecommons.org/licenses/by/4.0/{"}Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.",

year = "2025",

month = oct,

doi = "10.1103/dp5w-qxqc",

language = "英语",

volume = "15",

journal = "Physical Review X",

issn = "2160-3308",

publisher = "American Physical Society",

number = "4",

}

Ji, JB, Guo, Z, Driver, T, Trevisan, CS, Cesar, D, Cheng, X, Duris, J, Franz, PL, Glownia, J, Gong, X, Hammerland, D, Han, M, Heck, S, Hoffmann, M, Kamalov, A, Larsen, KA, Li, X, Lin, MF, Liu, Y, McCurdy, CW, Obaid, R, O'Neal, JT, Rescigno, TN, Robles, RR, Sudar, N, Walter, P, Wang, AL, Wang, J, Wolf, TJA, Zhang, Z, Ueda, K, Lucchese, RR, Marinelli, A, Cryan, JP & Wörner, HJ 2025, 'Attosecond X-Ray Core-Level Chronoscopy of Aromatic Molecules', Physical Review X, vol. 15, no. 4, 041031. https://doi.org/10.1103/dp5w-qxqc

TY - JOUR

T1 - Attosecond X-Ray Core-Level Chronoscopy of Aromatic Molecules

AU - Ji, Jia Bao

AU - Guo, Zhaoheng

AU - Driver, Taran

AU - Trevisan, Cynthia S.

AU - Cesar, David

AU - Cheng, Xinxin

AU - Duris, Joseph

AU - Franz, Paris L.

AU - Glownia, James

AU - Gong, Xiaochun

AU - Hammerland, Daniel

AU - Han, Meng

AU - Heck, Saijoscha

AU - Hoffmann, Matthias

AU - Kamalov, Andrei

AU - Larsen, Kirk A.

AU - Li, Xiang

AU - Lin, Ming Fu

AU - Liu, Yuchen

AU - McCurdy, C. William

AU - Obaid, Razib

AU - O'Neal, Jordan T.

AU - Rescigno, Thomas N.

AU - Robles, River R.

AU - Sudar, Nicholas

AU - Walter, Peter

AU - Wang, Anna L.

AU - Wang, Jun

AU - Wolf, Thomas J.A.

AU - Zhang, Zhen

AU - Ueda, Kiyoshi

AU - Lucchese, Robert R.

AU - Marinelli, Agostino

AU - Cryan, James P.

AU - Wörner, Hans Jakob

N1 - Publisher Copyright: © 2025 authors. Published by the American Physical Society. Published by the American Physical Society under the terms of the "https://creativecommons.org/licenses/by/4.0/"Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.

PY - 2025/10

Y1 - 2025/10

N2 - Attosecond photoemission or photoionization delays are a unique probe of the structure and the electronic dynamics of matter. However, the spectral congestion of valence photoelectron spectra sets fundamental limits to the complexity of systems that can be studied, and the delocalization of valence electron wave functions blurs the spatial origin of the photoelectron wave packet. Using attosecond x-ray pulses from LCLS, we demonstrate the key advantages of measuring core-level delays: The photoelectron spectra remain atomlike, the measurements become element specific, and the observed scattering dynamics originate from a pointlike source when multicenter interference effects are negligible. We exploit these unique features to reveal the effects of changing functional groups (C-H vs N) and symmetry on attosecond scattering dynamics by measuring and calculating the photoionization delays between N-1s and C-1s core shells of a series of aromatic azabenzene molecules. Remarkably, the delays increase with the number of nitrogen atoms in the molecule and reveal multiple resonances. We identify two previously unknown mechanisms regulating the associated attosecond dynamics, namely the enhanced confinement of the trapped wave function with the replacement of C-H groups by N atoms and the decrease of the coupling strength among the photoemitted partial waves with increasing symmetry. This study demonstrates the unique opportunities opened by measurements of core-level photoionization delays for unraveling attosecond electron dynamics in complex matter.

AB - Attosecond photoemission or photoionization delays are a unique probe of the structure and the electronic dynamics of matter. However, the spectral congestion of valence photoelectron spectra sets fundamental limits to the complexity of systems that can be studied, and the delocalization of valence electron wave functions blurs the spatial origin of the photoelectron wave packet. Using attosecond x-ray pulses from LCLS, we demonstrate the key advantages of measuring core-level delays: The photoelectron spectra remain atomlike, the measurements become element specific, and the observed scattering dynamics originate from a pointlike source when multicenter interference effects are negligible. We exploit these unique features to reveal the effects of changing functional groups (C-H vs N) and symmetry on attosecond scattering dynamics by measuring and calculating the photoionization delays between N-1s and C-1s core shells of a series of aromatic azabenzene molecules. Remarkably, the delays increase with the number of nitrogen atoms in the molecule and reveal multiple resonances. We identify two previously unknown mechanisms regulating the associated attosecond dynamics, namely the enhanced confinement of the trapped wave function with the replacement of C-H groups by N atoms and the decrease of the coupling strength among the photoemitted partial waves with increasing symmetry. This study demonstrates the unique opportunities opened by measurements of core-level photoionization delays for unraveling attosecond electron dynamics in complex matter.

UR - https://www.scopus.com/pages/publications/105022700933

U2 - 10.1103/dp5w-qxqc

DO - 10.1103/dp5w-qxqc

M3 - 文章

AN - SCOPUS:105022700933

SN - 2160-3308

VL - 15

JO - Physical Review X

JF - Physical Review X

IS - 4

M1 - 041031

ER -

Attosecond X-Ray Core-Level Chronoscopy of Aromatic Molecules

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