Ewa Erdmann - Profil naukowy - MOST Wiedzy

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Centrum Transferu Wiedzy i Technologii
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Wybrane publikacje

  • Roadmap on dynamics of molecules and clusters in the gas phase

    • H. Zettergren
    • A. Domaracka
    • T. Schlathölter
    • P. Bolognesi
    • S. Díaz-Tendero
    • M. Łabuda
    • S. Tosic
    • S. Maclot
    • P. Johnsson
    • A. Steber... i 34 innych

    - EUROPEAN PHYSICAL JOURNAL D - Rok 2021

    This roadmap article highlights recent advances, challenges and future prospects in studies of the dynamics of molecules and clusters in the gas phase. It comprises nineteen contributions by scientists with leading expertise in complementary experimental and theoretical techniques to probe the dynamics on timescales spanning twenty orders of magnitudes, from attoseconds to minutes and beyond, and for systems ranging in complexity...

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  • Furan Fragmentation in the Gas Phase: New Insights from Statistical and Molecular Dynamics Calculations

    - JOURNAL OF PHYSICAL CHEMISTRY A - Rok 2018

    We present a complete exploration of the different fragmentation mechanisms of furan (C4H4O) operating at low and high energies. Three different theoretical approaches are combined to determine the structure of all possible reaction intermediates, many of them not described in previous studies, and a large number of pathways involving three types of fundamental elementary mechanisms: isomerization, fragmentation, and H/H2 loss...

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  • A general approach to study molecular fragmentation and energy redistribution after an ionizing event

    • E. Erdmann
    • N. Aguirre
    • S. Indrajith
    • J. Chiarinelli
    • A. Domaracka
    • P. Rousseau
    • B. A. Huber
    • P. Bolognesi
    • R. Richter
    • L. Avaldi... i 3 innych

    - PHYSICAL CHEMISTRY CHEMICAL PHYSICS - Rok 2021

    We propose to combine quantum chemical calculations, statistical mechanical methods, and photoionization and particle collision experiments to unravel the redistribution of internal energy of the furan cation and its dissociation pathways. This approach successfully reproduces the relative intensity of the different fragments as a function of the internal energy of the system in photoelectron–photoion coincidence experiments and...

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