Ultrafast and Ultraslow Proton-Transfer Dynamics Induced by Formic Acid Dimer Ionization

Saroj Barik; Ester Livshits; Roi Baer; Daniel Strasser

doi:10.1021/acs.jpca.5c02619

Ultrafast and Ultraslow Proton-Transfer Dynamics Induced by Formic Acid Dimer Ionization

Saroj Barik
, Ester Livshits
, Roi Baer^*
, Daniel Strasser^*

^*Corresponding author for this work

Institute of Chemistry

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

Abstract

Proton-transfer dynamics in hydrogen-bonded dimers are important for understanding debated mechanisms of radiation damage to DNA base pairs. Using coincidence photofragment imaging in ultrafast extreme-ultraviolet pump and near-IR probe experiments on the formic acid dimer, we observed a transient enhancement (150 fs) of the protonated monomer signal. This correlates with ab initio molecular dynamics simulations of the ionization induced dynamics, showing concerted proton transfer and dimer ring opening in a metastable dimer. Coincidence analysis revealed the ultraslow mechanism of the metastable dimer cation on the microsecond time scale. The ultraslow dynamics were attributed to a barrier for the structural rearrangement of the deprotonated moiety from an HCOO to an OCOH geometry. Moreover, ultraslow channels of protonated monomer ions to form H₃O⁺+ CO and H₂O + CHO⁺were observed and interpreted as dissociation of hot photoions, involving nontrivial hydrogen migration.

Original language	English
Pages (from-to)	7768-7774
Number of pages	7
Journal	Journal of Physical Chemistry A
Volume	129
Issue number	34
DOIs	https://doi.org/10.1021/acs.jpca.5c02619
State	Published - 28 Aug 2025

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© 2025 American Chemical Society

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abstract = "Proton-transfer dynamics in hydrogen-bonded dimers are important for understanding debated mechanisms of radiation damage to DNA base pairs. Using coincidence photofragment imaging in ultrafast extreme-ultraviolet pump and near-IR probe experiments on the formic acid dimer, we observed a transient enhancement (150 fs) of the protonated monomer signal. This correlates with ab initio molecular dynamics simulations of the ionization induced dynamics, showing concerted proton transfer and dimer ring opening in a metastable dimer. Coincidence analysis revealed the ultraslow mechanism of the metastable dimer cation on the microsecond time scale. The ultraslow dynamics were attributed to a barrier for the structural rearrangement of the deprotonated moiety from an HCOO to an OCOH geometry. Moreover, ultraslow channels of protonated monomer ions to form H3O++ CO and H2O + CHO+were observed and interpreted as dissociation of hot photoions, involving nontrivial hydrogen migration.",

author = "Saroj Barik and Ester Livshits and Roi Baer and Daniel Strasser",

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AU - Barik, Saroj

AU - Livshits, Ester

AU - Baer, Roi

AU - Strasser, Daniel

PY - 2025/8/28

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N2 - Proton-transfer dynamics in hydrogen-bonded dimers are important for understanding debated mechanisms of radiation damage to DNA base pairs. Using coincidence photofragment imaging in ultrafast extreme-ultraviolet pump and near-IR probe experiments on the formic acid dimer, we observed a transient enhancement (150 fs) of the protonated monomer signal. This correlates with ab initio molecular dynamics simulations of the ionization induced dynamics, showing concerted proton transfer and dimer ring opening in a metastable dimer. Coincidence analysis revealed the ultraslow mechanism of the metastable dimer cation on the microsecond time scale. The ultraslow dynamics were attributed to a barrier for the structural rearrangement of the deprotonated moiety from an HCOO to an OCOH geometry. Moreover, ultraslow channels of protonated monomer ions to form H3O++ CO and H2O + CHO+were observed and interpreted as dissociation of hot photoions, involving nontrivial hydrogen migration.

AB - Proton-transfer dynamics in hydrogen-bonded dimers are important for understanding debated mechanisms of radiation damage to DNA base pairs. Using coincidence photofragment imaging in ultrafast extreme-ultraviolet pump and near-IR probe experiments on the formic acid dimer, we observed a transient enhancement (150 fs) of the protonated monomer signal. This correlates with ab initio molecular dynamics simulations of the ionization induced dynamics, showing concerted proton transfer and dimer ring opening in a metastable dimer. Coincidence analysis revealed the ultraslow mechanism of the metastable dimer cation on the microsecond time scale. The ultraslow dynamics were attributed to a barrier for the structural rearrangement of the deprotonated moiety from an HCOO to an OCOH geometry. Moreover, ultraslow channels of protonated monomer ions to form H3O++ CO and H2O + CHO+were observed and interpreted as dissociation of hot photoions, involving nontrivial hydrogen migration.

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JO - Journal of Physical Chemistry A

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Ultrafast and Ultraslow Proton-Transfer Dynamics Induced by Formic Acid Dimer Ionization

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