New insight into the ultra-long lifetime of excitons in organic-inorganic perovskite： Reverse intersystem crossing

Recently, an effective exciton diffusion length L exceeding 100μm has been reported for organic- inorganic halide perovskites owing to both the high mobility and ultra-long lifetime of the excitons; however, the origin of ultra-long L is still unclear in nature. In some photoelectric materials, reverse intersystem crossing （RISC） from the triplet to the singlet state can enhance the quantum yield of pho- toluminescence greatly. In this study, our theoretical investigation indicated that the energy difference △E_st between the singlet state and the triplet state of CH_3NH_3Pbl_3 was less than 0.1 eV, which represents one crucial prerequisite for the occurrence of RISC. Meanwhile, the experimental results showed that the photoluminescence lifetime increased with the increasing temperature, a typical feature of RISC. Based on this study, we put forward the hypothesis that the ultra-long lifetime of excitons in organic-inorganic halide perovskite might be caused by the RISC process. This may provide a new insight into the important photophysical properties of such novel photovoltaic materials.

Inuence of Electron Donating Ability on Reverse Intersystem Crossing Rate for One Kind of Thermally Activated Delayed Fluorescence Molecules

First-principles calculations are applied for investigating influence of electron donating ability of donor groups in eight thermally activated delayed fluorescence（TADF） molecules on their geometrical structures and transition properties as well as reverse intersystem crossing（RISC） processes. Results show that the diphenylamine substitution in the donor part can slightly change the bond angle but decrease bond length between donor and acceptor unit except for the lowest triplet state（Ti） of carbazole-xanthone molecule. As the electron donating ability of donor groups is increased, the overlap between the highest occupied molecular orbital（HOMO） and the lowest unoccupied molecular orbital（LUMO） is decreased. As the diphenylamine groups are added in donor part, the delocalization of HOMO is enlarged,which brings a decreased energy gap(△ES1-T1) between the lowest singlet excited state（S1）and T1 state. Furthermore, with the calculated spin-orbit coupling coefficient(HSO), one finds that the larger value of ■ is, the faster the RISC is. The results show that all investigated molecules are promising candidates as TADF molecules. Overall, a wise molecular design strategy for TADF molecules,in which a small △ES1-T1 can be achieved by enlarging the delocalization of frontier molecular orbitals with large separation between HOMO and LUMO, is proposed.

Efficient and Fast X-Ray Luminescence in Organic Phosphors Through High-Level Triplet-Singlet Reverse Intersystem Crossing

Organic scintillators that efficiently generate bright triplet excitons are of critical importance for highperformance X-ray-excited luminescence in radiation detection.However,the nature of triplet-singlet spinforbidden transitions in these materials often result in long-lived phosphorescence,which is undesirable for ultrafast X-ray detection and imaging.Here we demonstrate that the effect of hybridized local and charge-transfer(HLCT)excited states enables organic scintillators to exhibit highly efficient and fast radioluminescence(RL)in response to X-ray irradiation.Our experimental and theoretical investigation shows that the oxidized 1,8-naphthalimide-phenothiazine dyad(OMNI-PTZ 2)with HLCT-excited states has an enhanced overlap integral of the highest occupied molecular orbital(HOMO)and lowest unoccupied molecular orbital(LUMO)on MNIπ-orbitals,and moderate donor–acceptor electron interactions.As a result,the RL of these crystals exhibits a 61-fold increase and its monoexponential decay lifetime is three orders of magnitude faster compared to its corresponding thermally activated delayed fluorescence(TADF)molecule MNI-PTZ 1.We further demonstrate the practical utility of the OMNI-PTZ 2(G)in high-performance X-ray detection and imaging,achieving an X-ray dose sensitivity of 97 nGy s−1 and an exceptional spatial resolution of 20 lp/mm.Our study provides a promising molecular design principle for utilizing triplet excitons to develop high-efficiency and fast X-ray scintillators for the development of next-generation flexible and stretchable X-ray imaging detectors.

Spin-orbit Coupling and Intersystem Crossing in 4H-Pyran-4-thione： CASSCF//TD-B3LYP Study

The intersystem crossing channels of gaseous 4H-pyran-4-thione were investigated using the CASSCF//TD-B3LYP methods and group theory. Using the effective one-electron spin-orbit Harniltonian, the strengths of spin-orbit coupling were estimated, which plays an essential role in the spin transitions between different spin states. Calculated results show that phosphorescence and non-radiative decay via intersystem crossing to the So state are concurrent processes occurring at the T1 state. A rapid depletion of the S1 state via intersystem crossing to the T1 state can be mediated by the T2 state, if spin relaxation is fast within the triplet levels. Our calculated results are in close agreement with experimental observations.

Aggregation Turns BODIPY Fluorophores into Photosensitizers:Reversibly Switching Intersystem Crossing On and Off for Smart Photodynamic Therapy

We report for the first time a practical and simple supramolecular approach to turn fluorophores into photosensitizers(PSs).Using boron dipyrromethene(BODIPY)as a proof-of-concept,eight BODIPY derivatives manifest bright fluorescence and generate negligible singlet oxygen in solution.In contrast,aggregation fails to emit fluorescence and enhances singlet oxygen generation.Experimentally,these aggregates have excellent photodynamic therapy(PDT)performance,and one even exhibits much stronger photocytotoxicity than the commercialized PS Ce6 under identical conditions.Theoretical studies show that this property originated from significantly reduced energy gaps between relevant excited singlet and triplet states,leading to considerably improved intersystem-crossing efficiency.Importantly,a simple disaggregation recovers the original properties of the fluorophores.This reversible switching property between fluorophores and PSs assists the development of smart PDT systems,in which singlet oxygen generation in tumors can be controlled in an intelligent manner after PDT treatment.The present work provides a novel strategy to design heavy-atom-free PSs and may pave the way to the development of smart PDT systems.

Enhancing Intersystem Crossing by Intermolecular Dimer-Stacking of Cyanine as Photosensitizer for Cancer Therapy

Development of new photosensitizers(PSs)with high singlet oxygen quantumyield and minimal side effects is of great interest in photodynamic therapy(PDT).Herein,a facile strategy to significantly improve photosensitization has been demonstrated for the first time with two pentamethine dyes connected by a varying alkyl chain resulting in a series of cyanine dimers.The photophysical properties of the dimerswere studied with steady-state optical spectroscopies,a timecorrelated single photon counting technique,and laser flash photolysis spectrometry.X-ray crystallography confirmed that the molecular packing modes of Cy-Bu-D and Cy-He-D were dominated by H-aggregation.The H-aggregation by dimerization suppresses the radiative singlet decay,which helps to stabilize the highly efficient triplet excitation state.Moreover,the dimers show more intensewavelength absorption in the nearinfrared(ɛ1.5-2.0 times more than monomer Cy-H at 650 nm),better singlet oxygen quantum yield,and a longer triplet-state lifetime than monomer Cy-H,providing excellent performance as a triplet PS.In vivo experiments demonstrated that Cy-He-D successfully suppresses tumor growth after PDT treatment.This work is beneficial to the design of novel heavy atom free PSs for PDT-based theranostic systems.

A multi-dimensional microcanonical Monte Carlo study of S_0→T_1 intersystem crossing of isocyanic acid

A general formula for the multi-dimensional Monte Carlo microcanonical nonadiabatic rate constant expressed in configuration space is applied to calculate the rate of intersystem crossing(ISC) between the ground(S0) and first excited triplet(T1) states for isocyanic acid.One-,two-and three-dimensional potential energy surfaces are constructed by coupled-cluster single-double CCSD calculations,which are used for Monte Carlo sampling.The calculated S0→T1 ISC rate is in good agreement with experimental findings,which gives us a reason to believe that the multi-dimensional Monte Carlo microcanonical nonadiabatic rate theory is a very effective method for calculating nonadiabatic transition rate of a polyatomic molecule.

Crossed Molecular Beams and Theoretical Studies of the O(~3P)+1,2-Butadiene Reaction:Dominant Formation of Propene+CO and Ethylidene+Ketene Molecular Channels

Detailed understanding of the mechanism of the combustion relevant multichannel reactions of O(3P) with unsaturated hydrocarbons (UHs) requires the identification of all primary reaction products, the determination of their branching ratios and assessment of intersystem crossing (ISC) between triplet and singlet potential energy surfaces (PESs). This can be best achieved combining crossed-molecular-beam (CMB) experiments with universal, soft ionization, mass-spectrometric detection and time-of-flight analysis to high-level ab initio electronic structure calculations of triplet/singlet PESs and RRKM/Master Equation computations of branching ratios (BRs) including ISC. This approach has been recently demonstrated to be successful for O(3P) reactions with the simplest UHs (alkynes, alkenes, dienes) containing two or three carbon atoms. Here, we extend the combined CMB/theoretical approach to the next member in the diene series containing four C atoms, namely 1,2-butadiene (methylallene) to explore how product distributions, branching ratios and ISC vary with increasing molecular complexity going from O(3P))+propadiene to O(3P)+1,2-butadiene. In particular, we focus on the most important, dominant molecular channels, those forming propene+CO (with branching ratio ∽0.5) and ethylidene+ketene (with branching ratio ∽0.15), that lead to chain termination, to be contrasted to radical forming channels (branching ratio ∽0.35) which lead to chain propagation in combustion systems.

卤代姜黄素衍生物的合成及其对副溶血性弧菌的光动力灭活作用

为提升姜黄素(curcumin,Cur)的光动力灭活(photodynamic inactivation,PDI)效果,合成新型卤代姜黄素衍生物(X-cur,X=F、Cl、Br)。通过测定X-cur的紫外-可见吸收光谱和荧光光谱,对比X-cur的单线态氧(^(1)O_(2))生成能力并辅助激发态理论计算结果,分析筛选出具有PDI潜力的姜黄素衍生物。结果表明:随着非金属重原子卤素相对分子质量的增加,其自旋耦合作用逐渐增强,导致Br-cur具有最小的单重激发态(S_(1))和三重激发态(T_(3))能级差ΔE_(st(S1-T3))(0.140 eV)和最大的自旋轨道耦合值(0.642262 cm^(-1)),说明Br-cur最容易发生系间窜越过程进入到T_(3);此外,Br-cur相比于Cur和其他卤代姜黄素具有最小的S_(1)和基态(S_(0))间能级差(3.260 eV);以上两因素导致Br-cur极易被光激发且具有最高的^(1)O_(2)生成能力;在对水产品中典型食源性致病菌副溶血性弧菌(Vibrio parahaemolyticus)的PDI实验中,Br-cur的PDI作用依赖于其使用浓度和光照时间,且PDI效果显著高于Cur对照组,是极具应用潜力的新型PDI光敏剂。

C-S Activation of CS2 by Nb＋ in Gas Phase

The reaction of Nb＋ with CS2, producing cationic transition-metal sulfide and CS, was taken as a representative example to elucidate the overall mechanism of reactions of second- row early transition metal ions with CS2. The reactions in both triplet and quintet state were studied by using the UB3LYP density functional method with the Stuttgart pseudo potentials and corresponding basis sets for Nb＋ and the standard 6-311＋G（2d） basis sets for C and S. The geometries for reactants, the transition states, and the products were completely optimized. All the transition states were verified by vibrational analysis and intrinsic reaction coordinate calculations. The results show that the reaction mechanism between niobium ion and CS2 is an insertion-elimination mechanism. Intersystem crossing may occur in the reaction Nb＋ with CS2 and a minimum energy crossing point was found.

利用磁致发光曲线研究Rubrene器件中激子分裂和湮没过程

为了研究Rubrene分子中激发态的能量共振和分子间π-π共轭的特性对有机磁效应的影响,本文制备了基于不同浓度和厚度的Rubrene有机发光器件,并在不同温度下测量了器件的电致发光磁效应(magnetoelectroluminescence,MEL).实验发现,发光层中Rubrene的厚度和浓度均可以对器件中的MEL产生较大的影响,室温下MEL的高场值随Rubrene层厚度的增加而增加,并在30 nm之后逐步趋于饱和;随着Rubrene分子的浓度和测量温度的降低,MEL高场增加的幅度逐渐减小,甚至在低温时出现高场下降.通过对实验曲线进行数值拟合,认为Rubrene分子之间形成的π-π共轭结构有助于双分子相互作用的发生,单重态激子分裂、三重态激子之间的湮没和单一三重态极化子对的系间窜越三种过程在器件中相互竞争导致了所得MEL的变化.本工作有助于加深对有机光电子器件内部机理的认识.

Au^+(~1S,~3D)与N_2O(~1∑^+)反应机理的理论研究

采用密度泛函B3LYP方法,O和N用6-311+G*基组,Au+用赝势基组(8s7p6d)/[6s5p3d],研究了Au+(~1S,~3D)离子和N2O(~1∑^+)分子的反应机理.报道了在基态单重态和激发三重态势能面上各反应物、中间体和过渡态的构型特征及能量.结果表明,两个主反应通道Au+(1S)+N_2O(~1∑^+)→1NA-Complex-1→1NA-TS1→1NA-Complex-2→1NA-Crossing→[3OAuNN]+和Au+(1S)+N2O(~1∑^+)→1NB-Complex→1NB-Crossing→[AuNN(1∑+)]++O(3P)都需经过反应交叉势能面,出现“系间窜越”.用内禀坐标单点计算垂直激发态的方法确定了势能面交叉点,并用含时密度泛函TD-B3LYP方法进一步探讨了自旋翻转机理.

气相中Co^+催化N_2O与C_2H_6循环反应催化剂活性的理论研究

采用密度泛函理论UB3LYP方法对Co+在三重态及五重态势能面上催化N2O与C2H6进行循环反应的两态反应机理进行了研究.运用Harvery方法优化了两自旋态势能面5个最低能量交叉点(MECP),计算了MECP处自旋-轨道耦合作用. 采用Landau-Zener公式计算了自旋翻转处的系间窜越几率,各MECP处均可发生有效系间窜越.通过应用Kozuch提出的能量跨度模型,Co+催化N2O与C2H6在298K下反应生成CH3CHO时有最大的TOF值3.35×10–21 s–1.

RN_3解离反应中交叉点构型及电子密度拓扑分析

采用CASSCF(10,8)/3-21G方法优化了CH3N3,CH3CH2N3,(CH3)2CHN3和(CH3)3CN3单重态和三重态解离过程中交叉点的几何构型.4个反应中的交叉点的几何构型参数比较接近.采用电子密度拓扑分析方法计算了交叉点的电子密度拓扑性质.研究发现:交叉点在单重态和三重态途径上N(2)N(3)键的特性变化较大,在三重态反应途径上N(2)N(3)键更容易断裂.

2-甲基吡嗪分子激发态系间交叉过程的飞秒时间分辨光电子影像研究

飞秒时间分辨光电子影像技术和飞秒时间分辨质谱技术相结合,研究了2-甲基吡嗪分子电子激发态超快非绝热弛豫动力学.用323 nm光作为泵浦光,把2-甲基吡嗪分子激发到第一激发态S1,用400 nm光探测激发态演化过程.通过时间分辨质谱技术测得S1态的寿命为98 ps.实验中,实时观察到了单重态S1向三重态T1的系间交叉过程.通过分析发现,跟吡嗪分子S1态的动力学过程不同,2-甲基吡嗪分子激发到S1态后,不仅S1→T1系间交叉过程是S1态主要衰减通道,S1→S0内转换过程也是S1态另一个主要衰减通道.发挥飞秒时间分辨光电子影像技术的优点,实验上得到不同泵浦-探测时间延迟的光电子角分布,从角分布信息结合光电子能谱信息,尝试观察2-甲基吡嗪分子的非绝热无场准直,但由于2-甲基吡嗪分子对称性比吡嗪分子更低,对称性更低分子准直现象的观察更有挑战性,在实验中未能观察到非绝热准直动力学.本工作为2-甲基吡嗪分子S1态非绝热弛豫动力学提供了较清楚的物理图像.

苯乙炔分子电子激发态超快动力学研究

采用飞秒时间分辨质谱技术结合飞秒时间分辨光电子影像技术研究了苯乙炔分子电子激发态超快非绝热弛豫动力学.用235 nm光作为泵浦光,将苯乙炔分子激发到第二激发态S2,用400 nm光探测激发态的演化过程.时间分辨的母体离子的变化曲线用指数和高斯函数卷积得到不同的两个组分,一个是超快衰减组分,时间常数为116 fs,一个是慢速组分,时间常数为106 ps.通过分析时间分辨的光电子影像得到光电子动能分布,结合时间分辨光电子能谱数据发现,时间常数为116 fs的快速组分反映了S2态向S1态的内转换过程.实验还表明S1态通过内转换被布局后向T1态的系间窜跃过程为重要的衰减通道.本工作为苯乙炔分子S2态非绝热弛豫动力学提供了较清晰的物理图像.

四配位铂磷光发射体结构与光物理性质关系的理论研究

定量理解光物理过程对于开发新型高效发射极至关重要.优化提升二价铂配合物磷光量子效率是提升基于金属铂有机发光二极管发光效率的关键.本文借助密度泛函理论计算,探讨了一类平面四齿配位二价铂配合物磷光辐射的微观机制,包括自旋轨道耦合积分、辐射寿命、速率常数、跃迁偶极矩和隙间蹿跃通道.综合研究发现,沿着N→Pt方向推电子,可有效屏蔽非辐射跃迁过程,从而提升磷光发射效率.本文将为高效发射器的分子工程学设计提供必要的指导.

3CzIPN分子热活化延迟荧光机制的理论研究

运用含时密度泛函理论(TD-DFT)方法,在以苯为溶剂的可极化连续模型(PCM)下,研究了2,4,6-三(9-咔唑基)-间苯二腈(3CzIPN)分子发生热活化延迟荧光(TADF)的反应机制.计算结果表明,3CzIPN分子的单-三态能量差非常小,仅为0.124 eV,这对反系间窜越(RISC)非常有利.此外,3CzIPN分子的RISC速率达到了104数量级,表明3CzIPN分子可能是一个潜在的TADF发射体.

非血红素铁超氧化物活化丙烯分子多态反应机理的理论研究（英文）

采用密度泛函DFT-B3LYP理论对非血红素铁超氧化物活化丙烯分子多态反应机理进行了探讨.研究结果表明氢原子抽取过程遵守单态反应机制,主要在基态高自旋七重态势能面进行,且具有较低活化能(ΔG~≠=65.6 k J·mol^(-1)),非血红素铁超氧化物可以作为有效氧化剂抽取氢原子。单态反应机制可能归因于近来建议的交换-加强反应原则(EER,铁中心具有较大交换稳定作用)。对于O-O键的活化,在CASSCF(10,8)/6-31+G(d)//TZVP水平下,势能面交叉区内,高自旋七重态(S1)和五重态(Q0)的自旋-轨道耦合(SOC)常数分别为2.26和2.19 cm^(-1)。轨道分析表明两条发生翻转自旋轨道具有相同空间组成(π*sub),SOC禁阻,因此通过SOC作用反应体系不可能有效地从七重态(S=3)势能面系间穿越到五重态(S=2)势能面,系间穿越可能发生在反应最后的退出阶段。

AcCz-2TP分子热活化延迟荧光机制的理论研究

运用半经典的Marcus理论,结合密度泛函理论和含时密度泛函理论的计算方法,研究了AcCz-2TP分子的热活化延迟荧光(TADF)机制.研究结果表明,AcCz-2TP分子的系间窜跃速率和反系间窜跃速率分别为9. 48×106和2. 40×103s-1,能够与其荧光辐射速率(2. 49×104s-1)和磷光辐射速率(0. 32 s-1)互相竞争.目前的计算结果合理地解释了基于AcCz-2TP分子的有机发光二极管器件的外量子效率较低的原因.