Impact of nuclear effects on the ultrafast dynamics of an organic/inorganic mixed-dimensional interface

IF 2.9 Q3 CHEMISTRY, PHYSICAL
Matheus Jacobs, Karen Fidanyan, Mariana Rossi and Caterina Cocchi
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Abstract

Electron dynamics at weakly bound interfaces of organic/inorganic materials are easily influenced by large-amplitude nuclear motion. In this work, we investigate the effects of different approximations to the equilibrium nuclear distributions on the ultrafast charge-carrier dynamics of a laser-excited hybrid organic/inorganic interface. By considering a prototypical system consisting of pyrene physisorbed on a MoSe2 monolayer, we analyze linear absorption spectra, electronic density currents, and charge-transfer dynamics induced by a femtosecond pulse in resonance with the frontier-orbital transition in the molecule. The calculations are based on ab initio molecular dynamics with classical and quantum thermostats, followed by time-dependent density-functional theory coupled to multi-trajectory Ehrenfest dynamics. We impinge the system with a femtosecond (fs) pulse of a few hundred GW cm−2 intensity and propagate it for 100 fs. We find that the optical spectrum is insensitive to different nuclear distributions in the energy range dominated by the excitations localized on the monolayer. The pyrene resonance, in contrast, shows a small blue shift at finite temperatures, hinting at an electron-phonon-induced vibrational-level renormalization. The electronic current density following the excitation is affected by classical and quantum nuclear sampling through suppression of beating patterns and faster decay times. Interestingly, finite temperature leads to a longer stability of the ultrafast charge transfer after excitation. Overall, the results show that the ultrafast charge-carrier dynamics are dominated by electronic rather than by nuclear effects at the field strengths and time scales considered in this work.
核效应对有机/无机混维界面超快动力学的影响
有机/无机材料弱结合界面上的电子动力学很容易受到大振幅核运动的影响。在这项工作中,我们研究了平衡核分布的不同近似值对激光激发的有机/无机混合界面的超快电荷载流子动力学的影响。通过考虑由物理吸附在 MoSe2 单层上的芘组成的原型系统,我们分析了线性吸收光谱、电子密度电流以及飞秒脉冲与分子中前沿轨道转变共振诱导的电荷转移动力学。计算基于带有经典和量子恒温器的 ab initio 分子动力学,然后是与多轨迹 Ehrenfest 动力学相耦合的时变密度泛函理论。我们用强度为几百 GW cm-2 的飞秒 (fs) 脉冲冲击该系统并传播 100 fs。我们发现,在单层局部激发的能量范围内,光谱对不同的核分布并不敏感。相反,芘共振在有限温度下显示出微小的蓝移,暗示了电子-声子诱导的振动级重正化。激发后的电子电流密度受到经典和量子核取样的影响,跳动模式受到抑制,衰变时间加快。有趣的是,有限温度导致激发后的超快电荷转移具有更长的稳定性。总之,研究结果表明,在本研究考虑的场强和时间尺度下,超快电荷载流子动力学是由电子效应而非核效应主导的。
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
CiteScore
3.70
自引率
11.50%
发文量
46
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