Understanding Contrasting S2→S1 Internal Conversion Rates in Boron-Dipyrromethene Derivatives via Multi-Configuration Time-Dependent Hartree Method

IF 2.9 3区化学 Q3 CHEMISTRY, PHYSICAL

Physical Chemistry Chemical Physics Pub Date : 2025-09-30 DOI:10.1039/d5cp02771c

Neethu Anand, Munnyon Kim, Changmin Lee, Jinhyuk Ma, Taiha Joo

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引用次数: 0

Abstract

Internal conversion (IC) dynamics from higher-lying to lower electronic states following photoexcitation are often described as ultrafast, occurring in much less than 1 ps. However, IC processes can exhibit a range of time scales, depending critically on the energetic landscape of excited-state manifolds and the strength of vibronic couplings that drive nonadiabatic transitions. These dynamics play a fundamental role in most photochemical and photophysical applications. A previous time-resolved fluorescence study revealed that two structurally analogous boron-dipyrromethene (BODIPY) molecules, PM650 and PM597, exhibit markedly different IC rates, despite both undergoing ultrafast IC in <100 fs from the S3/S2 to the S1 state. Nuclear wave packets persisting in the S1 state after the IC were also observed by time-resolved fluorescence. To elucidate the origin of these divergent IC rates and the nature of vibronic interactions among excited states, we performed theoretical simulations using the multiconfiguration time-dependent Hartree (MCTDH) method. Our results reveal nonadiabatic decay pathways mediated by vibronically coupled S1, S2, and S3 potential energy surfaces, with multiple conical intersections (CIs) enabling the IC processes. The IC rates obtained from the MCTDH simulations are in good agreement with the experimental observations, including the contrasting rates for PM650 and PM597. Importantly, the proximity of CIs to the Franck–Condon region was found to significantly influence IC efficiency. As more vibrational modes were incorporated into the model, a consistent acceleration of the IC dynamics was observed, underscoring the role of multimode effects in nonadiabatic transitions through CIs. Additionally, coherent vibrational spectra of the S1 state, generated from nuclear densities computed via MCTDH following excitation to higher states, were found to match experimental results closely, further supporting the conclusions of this study. Overall, these findings advance our understanding of the intricate excited-state dynamics and highlight the critical role of vibronic coupling and CIs in ultrafast IC.

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利用多构型时变Hartree方法对比硼-二吡咯甲烷衍生物中S2→S1的内转化率

光激发后从高能级到低能级的内部转换（IC）动力学通常被描述为超快，发生在远小于1ps的时间内。然而，IC过程可以表现出一系列的时间尺度，这主要取决于激发态流形的能量景观和驱动非绝热跃迁的振动耦合的强度。这些动力学在大多数光化学和光物理应用中起着基本的作用。先前的一项时间分辨荧光研究表明，两个结构类似的硼-二吡啶（BODIPY）分子PM650和PM597表现出明显不同的集成电路速率，尽管它们都在100秒内从S3/S2到S1态进行了超快集成电路。通过时间分辨荧光也观察到核波包在IC后持续在S1状态。为了阐明这些分散的IC速率的起源和激发态之间的振动相互作用的性质，我们使用多组态时间依赖Hartree （MCTDH）方法进行了理论模拟。我们的研究结果揭示了由振动耦合的S1， S2和S3势能面介导的非绝热衰变途径，多个圆锥相交（CIs）使IC过程成为可能。MCTDH模拟得到的IC速率与实验观测结果吻合较好，包括PM650和PM597的对比速率。重要的是，发现CIs靠近frank - condon区域对IC效率有显著影响。随着更多的振动模式被纳入模型，观察到IC动力学的一致加速，强调了多模效应在通过CIs的非绝热转变中的作用。此外，由MCTDH计算的核密度在激发到更高态后产生的S1态相干振动谱与实验结果非常吻合，进一步支持了本研究的结论。总的来说，这些发现促进了我们对复杂激发态动力学的理解，并强调了振动耦合和CIs在超快集成电路中的关键作用。

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来源期刊

Physical Chemistry Chemical Physics 化学-物理：原子、分子和化学物理

CiteScore

5.50

自引率

9.10%

发文量

2675

审稿时长

2.0 months

期刊介绍： Physical Chemistry Chemical Physics (PCCP) is an international journal co-owned by 19 physical chemistry and physics societies from around the world. This journal publishes original, cutting-edge research in physical chemistry, chemical physics and biophysical chemistry. To be suitable for publication in PCCP, articles must include significant innovation and/or insight into physical chemistry; this is the most important criterion that reviewers and Editors will judge against when evaluating submissions. The journal has a broad scope and welcomes contributions spanning experiment, theory, computation and data science. Topical coverage includes spectroscopy, dynamics, kinetics, statistical mechanics, thermodynamics, electrochemistry, catalysis, surface science, quantum mechanics, quantum computing and machine learning. Interdisciplinary research areas such as polymers and soft matter, materials, nanoscience, energy, surfaces/interfaces, and biophysical chemistry are welcomed if they demonstrate significant innovation and/or insight into physical chemistry. Joined experimental/theoretical studies are particularly appreciated when complementary and based on up-to-date approaches.