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1. Ultrafast strong-field dissociation of vinyl bromide: An attosecond transient absorption spectroscopy and non-adiabatic molecular dynamics study

   https://doi.org/10.1063/4.0000102  

   Rott, Florian; Reduzzi, Maurizio; Schnappinger, Thomas; Kobayashi, Yuki; Chang, Kristina_F; Timmers, Henry; Neumark, Daniel_M; Vivie-Riedle, Regina_de; Leone, Stephen_R (June 2021, Structural Dynamics)

   Attosecond extreme ultraviolet (XUV) and soft x-ray sources provide powerful new tools for studying ultrafast molecular dynamics with atomic, state, and charge specificity. In this report, we employ attosecond transient absorption spectroscopy (ATAS) to follow strong-field-initiated dynamics in vinyl bromide. Probing the Br M edge allows one to assess the competing processes in neutral and ionized molecular species. Using ab initio non-adiabatic molecular dynamics, we simulate the neutral and cationic dynamics resulting from the interaction of the molecule with the strong field. Based on the dynamics results, the corresponding time-dependent XUV transient absorption spectra are calculated by applying high-level multi-reference methods. The state-resolved analysis obtained through the simulated dynamics and related spectral contributions enables a detailed and quantitative comparison with the experimental data. The main outcome of the interaction with the strong field is unambiguously the population of the first three cationic states, D1, D2, and D3. The first two show exclusively vibrational dynamics while the D3 state is characterized by an ultrafast dissociation of the molecule via C–Br bond rupture within 100 fs in 50% of the analyzed trajectories. The combination of the three simulated ionic transient absorption spectra is in excellent agreement with the experimental results. This work establishes ATAS in combination with high-level multi-reference simulations as a spectroscopic technique capable of resolving coupled non-adiabatic electronic-nuclear dynamics in photoexcited molecules with sub-femtosecond resolution. 

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2. Kramers–Kronig relation in attosecond transient absorption spectroscopy

   https://doi.org/10.1364/OPTICA.474960  

   Leshchenko, Vyacheslav; Hageman, Stephen_J; Cariker, Coleman; Smith, Gregory; Camper, Antoine; Talbert, Bradford_K; Agostini, Pierre; Argenti, Luca; DiMauro, Louis_F (January 2023, Optica)

   The Kramers–Kronig relation (KKR) has a wide range of applications in extreme ultraviolet (XUV) and x-ray spectroscopy. However, the validity of KKR for many of these applications has not been systematically studied, while it is known to require careful attention in nonlinear and pump–probe experiments in optical domain spectroscopy. Here, we study the validity of KKR in XUV attosecond transient absorption spectroscopy pump–probe measurements both experimentally and theoretically using argon Fano resonances as a case study. Experiments are enabled by a phase-resolved method dubbed Complex Attosecond Transient-absorption Spectroscopy (CATS). Although the estimations based on the rotating-wave approximation suggest that KKR violation could be expected in the studied case, our results validate KKR and provide a solid basis for its application in a broad range of attosecond spectroscopy experiments. 

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3. Mapping static core-holes and ring-currents with X-ray scattering

   https://doi.org/10.1039/D0FD00124D  

   Moreno Carrascosa, Andrés; Yang, Mengqi; Yong, Haiwang; Ma, Lingyu; Kirrander, Adam; Weber, Peter M.; Lopata, Kenneth (May 2021, Faraday Discussions)

   null (Ed.)

   Measuring the attosecond movement of electrons in molecules is challenging due to the high temporal and spatial resolutions required. X-ray scattering-based methods are promising, but many questions remain concerning the sensitivity of the scattering signals to changes in density, as well as the means of reconstructing the dynamics from these signals. In this paper, we present simulations of stationary core-holes and electron dynamics following inner-shell ionization of the oxazole molecule. Using a combination of time-dependent density functional theory simulations along with X-ray scattering theory, we demonstrate that the sudden core-hole ionization produces a significant change in the X-ray scattering response and how the electron currents across the molecule should manifest as measurable modulations to the time dependent X-ray scattering signal. This suggests that X-ray scattering is a viable probe for measuring electronic processes at time scales faster than nuclear motion. 

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4. Probing calcium solvation by XAS, MD and DFT calculations

   https://doi.org/10.1039/d0ra05905f  

   Yang, Feipeng; Liu, Yi-Sheng; Feng, Xuefei; Qian, Kun; Kao, Li Cheng; Ha, Yang; Hahn, Nathan T.; Seguin, Trevor J.; Tsige, Mesfin; Yang, Wanli; et al (July 2020, RSC Advances)

   The solvation shell structures of Ca 2+ in aqueous and organic solutions probed by calcium L-edge soft X-ray absorption spectroscopy (XAS) and DFT/MD simulations show the coordination number of Ca 2+ to be negatively correlated with the electrolyte concentration and the steric hindrance of the solvent molecule. In this work, the calcium L-edge soft XAS demonstrates its sensitivity to the surrounding chemical environment. Additionally, the total electron yield (TEY) mode is surface sensitive because the electron penetration depth is limited to a few nanometers. Thus this study shows its implications for future battery studies, especially for probing the electrolyte/electrode interface for electrochemical reactions under in situ /operando conditions. 

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5. The 2021 ultrafast spectroscopic probes of condensed matter roadmap

   https://doi.org/10.1088/1361-648x/abfe21  

   Lloyd-Hughes, J; Oppeneer, P M; Pereira dos Santos, T; Schleife, A; Meng, S; Sentef, M A; Ruggenthaler, M; Rubio, A; Radu, I; Murnane, M; et al (July 2021, Journal of Physics: Condensed Matter)

   Abstract In the 60 years since the invention of the laser, the scientific community has developed numerous fields of research based on these bright, coherent light sources, including the areas of imaging, spectroscopy, materials processing and communications. Ultrafast spectroscopy and imaging techniques are at the forefront of research into the light–matter interaction at the shortest times accessible to experiments, ranging from a few attoseconds to nanoseconds. Light pulses provide a crucial probe of the dynamical motion of charges, spins, and atoms on picosecond, femtosecond, and down to attosecond timescales, none of which are accessible even with the fastest electronic devices. Furthermore, strong light pulses can drive materials into unusual phases, with exotic properties. In this roadmap we describe the current state-of-the-art in experimental and theoretical studies of condensed matter using ultrafast probes. In each contribution, the authors also use their extensive knowledge to highlight challenges and predict future trends. 

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