Structure and spin of the low- and high-spin states of Fe²⁺(phen)₃ studied by x-ray scattering and emission spectroscopy.

IF 2.3 2区物理与天体物理 Q3 CHEMISTRY, PHYSICAL

Structural Dynamics-Us Pub Date : 2024-10-23 eCollection Date: 2024-09-01 DOI:10.1063/4.0000254

Victoria Kabanova, Mathias Sander, Matteo Levantino, Qingyu Kong, Sophie Canton, Marius Retegan, Marco Cammarata, Philipp Lenzen, Latévi Max Daku Lawson, Michael Wulff

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Abstract

The structure and spin of photoexcited Fe²⁺(phen)₃ in water are examined by x-ray scattering and x-ray emission spectroscopy with 100 ps time resolution. Excitation of the low-spin (LS) ground state (GS) to the charge transfer state ¹MLCT^* leads to the formation of a high-spin (HS) state that returns to the GS in 725 ps. Density functional theory (DFT) predicts a Fe-N bond elongation in HS by 0.19 Å in agreement with the scattering data. The angle between the ligands increases by 5.4° in HS, which allows the solvent to get 0.33 Å closer to Fe in spite of the expansion of the molecule. The rise in solvent temperature from the return of photoproducts to the GS is dominated by the formation dynamics of HS, ¹MLCT^* → HS, which is followed by a smaller rise from the HS → GS transition. The latter agrees with the 0.61 eV energy gap E(HS)-E(LS) calculated by DFT. However, the temperature rise from the ¹MLCT → HS transition is greater than expected, by a factor of 2.1, which is explained by the re-excitation of nascent HS^* by the 1.2 ps pump pulse. This hypothesis is supported by optical spectroscopy measurements showing that the 1.2 ps long pump pulse activates the HS^* → ⁵MLCT^* channel, which is followed by the ultrafast return to HS^* via intersystem crossing. Finally, the spins of the photoproducts are monitored by the K_β emission and the spectra confirm that the spins of LS and HS states are 0 and 2, respectively.

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利用 X 射线散射和发射光谱研究 Fe2+(phen)3 的低自旋态和高自旋态的结构和自旋。

通过 X 射线散射和 X 射线发射光谱，以 100 ps 的时间分辨率研究了水中光激发 Fe2+(phen)3 的结构和自旋。低自旋（LS）基态（GS）被激发到电荷转移态 1MLCT* 后形成了高自旋（HS）态，并在 725 ps 内返回到 GS。密度泛函理论（DFT）预测 HS 中的 Fe-N 键伸长了 0.19 Å，这与散射数据一致。在 HS 中，配体之间的夹角增加了 5.4°，这使得溶剂在分子膨胀的情况下仍能靠近 Fe 0.33 Å。光反应产物返回 GS 时溶剂温度的升高主要受 HS（1MLCT* → HS）的形成动力学影响，其次是 HS → GS 转变过程中的较小升高。后者与 DFT 计算出的 0.61 eV 能隙 E(HS)-E(LS) 相吻合。然而，1MLCT → HS 转变的温升比预期的要高 2.1 倍，这是因为新生 HS* 被 1.2 ps 泵脉冲再次激发。光学光谱测量结果表明，1.2 ps 长泵浦脉冲激活了 HS* → 5MLCT* 通道，随后通过系统间交叉超快返回 HS*，从而支持了这一假设。最后，通过 Kβ 发射监测光产物的自旋，光谱证实 LS 和 HS 状态的自旋分别为 0 和 2。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Structural Dynamics-Us CHEMISTRY, PHYSICALPHYSICS, ATOMIC, MOLECU-PHYSICS, ATOMIC, MOLECULAR & CHEMICAL

CiteScore

5.50

自引率

3.60%

发文量

审稿时长

16 weeks

期刊介绍： Structural Dynamics focuses on the recent developments in experimental and theoretical methods and techniques that allow a visualization of the electronic and geometric structural changes in real time of chemical, biological, and condensed-matter systems. The community of scientists and engineers working on structural dynamics in such diverse systems often use similar instrumentation and methods. The journal welcomes articles dealing with fundamental problems of electronic and structural dynamics that are tackled by new methods, such as: Time-resolved X-ray and electron diffraction and scattering, Coherent diffractive imaging, Time-resolved X-ray spectroscopies (absorption, emission, resonant inelastic scattering, etc.), Time-resolved electron energy loss spectroscopy (EELS) and electron microscopy, Time-resolved photoelectron spectroscopies (UPS, XPS, ARPES, etc.), Multidimensional spectroscopies in the infrared, the visible and the ultraviolet, Nonlinear spectroscopies in the VUV, the soft and the hard X-ray domains, Theory and computational methods and algorithms for the analysis and description of structuraldynamics and their associated experimental signals. These new methods are enabled by new instrumentation, such as: X-ray free electron lasers, which provide flux, coherence, and time resolution, New sources of ultrashort electron pulses, New sources of ultrashort vacuum ultraviolet (VUV) to hard X-ray pulses, such as high-harmonic generation (HHG) sources or plasma-based sources, New sources of ultrashort infrared and terahertz (THz) radiation, New detectors for X-rays and electrons, New sample handling and delivery schemes, New computational capabilities.