质子化的分子团簇中的氢键重排和溶剂效应引起的质子转移

综述了分子离子团簇中的氢键重排和溶剂效应引起的质子转移。用红外光谱研究离子阱光谱仪中的团簇离子的振动预解离光谱，并结合从头计算法（Ｂ３ＬＹＰ／６－３１Ｇ水平）分析了它们的详细动力学行为。     

第一性原理研究一维SiO2纳米材料的结构和性质

运用密度泛函理论，在6-31G(d)基组水平上，对二元环组成的SiO₂单链、双链纳米线和三元环组成的纳米管进行几何优化，并对其结合能、电子结构和振动频率进行计算.结果表明，平均结合能和能隙均随着SiO₂单元的增加单调变化.红外光谱的分析发现，径向和切向的振动频率与强度随着长度的变化有明显的移动.径向的振动频率向高频端移动，而切向的振动频率则向低频端移动，即SiO₂纳米材料中存在量子尺寸效应和各向异性现象. 关键词： 2纳米材料')" href="#">SiO₂纳米材料 能隙 振动光谱 尺寸效应     

从单分子到凝聚相水体系的理论描述：势能面和分子动力学最新进展

本文回顾了近十年来水体系的势能面与分子动力学理论研究的最新进展,包括水分子参与的气相反应,固体表面上的吸附与解离动力学,以及从团簇到凝聚相水的结构、振动光谱与统计力学模拟. 近年来再次发展起来的机器学习技术,例如结合置换不变多项式的神经网络,或结合基本不变量的神经网络,已被成熟应用于气相与固体表面体系的高精度势能面构造中. 对于团簇甚至凝聚相水体系,原子中心神经网络方法或基于核的高斯过程方法应用更为广泛. 此外,在多体展开框架下,在气相体系中发展起来的的方法也组成了高维度体系势函数构造的高精度方案. 当前凝聚相水体系面临的主要问题是高精度从头算数据集的积累,兼顾计算精度与效率的双杂化密度泛函是一种可能的解决方案. 在动力学理论方面,无论是化学反应截面计算还是振动光谱模拟,往往需要合理描述水分子中氢原子的量子效应,才能得到较为可靠的理论计算结果. 量子波包动力学方法已经在气相反应机理研究方面有深入的应用,也在包含数个水分子的团簇振动分析中有初步应用. 基于路径积分的分子动力学方法正在较大水团簇以及凝聚相水的结构与谱学模拟方面发挥重要作用.     

相干振动动力学和高分辨非线性光谱学：空气/二甲亚砜液体界面的比较

研究了空气/二甲亚砜界面C?H伸缩振动的自由诱导衰减的相干振动动力学和亚波数高分辨宽带和频振动光谱．对于特定分子体系,频率域光谱测量和时间域动力学测量原则上应获得相同的信息．但对具有耦合或者重叠在一起的若干振动模式的分子体系,通过时域或者频域测量以获取光谱和动力学信息细节均非易事．对于振动光谱并非过于复杂的空气/二甲亚砜界面,基于亚波数高分辨宽带和频振动光谱的频域测量较超快时域测量更有益于获取界面结构和相干动力学定量信     

基于溶剂化效应的BDE-15分子振动光谱增强特征振动研究

利用密度泛函与自洽反应场理论在B3LYP/6-31+G(d)水平下分别计算气态及24种不同极性溶剂中4,4’-二溴二苯醚(4,4’-dibrominated diphenyl ethers, BDE-15)的分子振动光谱(红外光谱、拉曼光谱),以气态分子振动光谱为基准,筛选出对溶剂极性敏感的特征振动作为指标构建溶剂对BDE-15振动光谱溶剂化效应指标体系,探究溶剂对BDE-15分子振动频率、红外/拉曼峰强溶剂化效应及综合效应,并寻求显著增强BDE-15分子特征振动频移/强度的溶剂。研究表明：从分子振动频率角度,溶剂极性敏感的(频移>1 cm-1)分子特征振动均为伸缩振和面外弯曲振,但24种溶剂对BDE-15分子振动频率溶剂化效应并不显著;从分子振动峰强角度,24种溶剂对BDE-15分子振动光谱峰强的增强效应主要发生在红外光谱的中低频区及拉曼光谱的高频区,其中起显著增强(红外/拉曼效应指标值分别大于6与5)的溶剂为醇类、乙腈、二甲亚砜、硝基苯;不同极性溶剂对BDE-15拉曼峰强溶剂化效应及综合效应指标值均表现出随溶剂介电常数增长由线性到对数的增长趋势,而红外峰强只保留低介电常数溶剂时的线性关系。利用上述BDE-15分子振动光谱峰强增强方法对BDE-153,BDE-154和BDE-209进行验证,醇类、乙腈、二甲亚砜、硝基苯对三者的振动光谱红外/拉曼峰强的效应指标值分别大于6与5,且最大峰强增倍数皆大于33,说明所建BDE-15分子振动光谱增强特征振动方法有助于进一步开展基于分子振动光谱的PBDEs同系物间辨识研究。     

D+HS反应的含时量子动力学研究

利用含时波包方法对D+HS交换和抽取通道进行量子动力学研究,动力学计算中所采用的势能面由高精度从头算能量点构建.在平动能0.0～2.0 eV区间内计算了反应物初始振转基态时的总反应几率和积分反应截面,并且计算了初始振动激发态对积分反应截面的影响.所有动力学计算均考虑了科里奥利耦合效应.在低平动能时抽取通道在反应中占主导地位,而交换通道在高平动能时占主导地位.在整个所研究的平能能区间内,反应物HS的振动激发对抽取和交换通道反应都有增强作用.     

丝素氨基酸寡肽链生长过程中的尺寸效应

运用密度泛函理论,对甘氨酸丙氨酸依次交替组成的13 条丝素寡肽链进行结构优化,并计算了平均结合能、偶极矩,绘出寡肽链的振动红外光谱. 计算结果发现,随着寡肽链的生长,平均结合能单调变化,典型官能团的红外特征峰均发生频移. 但官能团的伸缩振动和弯曲振动表现出相反的红移和蓝移趋势. 揭示出丝素氨基肽链的物理化学性质在生长过程存在尺寸效应及各向异性. 该现象源于同类官能团之间的耦合效应,以及分子内氢键作用对伸缩振动和弯曲振动具有不同的影响. 关键词： 寡肽 红外光谱 尺寸效应 奇偶效应     

非平行导线型边界下Maxwell-Chern-Simons场的Casimir效应

在路径积分量子化框架下，利用复变函数论中的保角变换与Plana求和公式，计算了（2＋1）维空间中两个非平行导线型边界下Maxwell-Chern-Simons场的Casimir效应.不引入任何截断参数，而得出有限的解析表达式. 关键词： Casimir效应 路径积分 保角变换 Plana求和公式     

夹具动力学效应的工程分析

振动夹具附加约束的客观存在，使得在研究振动试验模拟的有效性时必须充分考虑夹具附加约束的动力学效应。通过边界的动力学设计，可以使得改变了边界的试验系统能够满足给定的动力学特性要求，但这种分析的工程应用需要依靠复杂的工程与工具。文中提出了利用二自由度模型评估夹具动力学效应的工程方法，并通过数字模拟进行了方法的验证。     

分子激发态光谱和动力学

分子激发态光谱和动力学对于了解分子的电子结构及电子运动、核振动和分子转动之间的相互作用有重要的意义.我们建立起了一套红外-红外双共振实验平台,开展了碱金属双原子分子微扰增强双共振研究,取得了一些重要结果.利用XUV激光结合高分辨光电子能谱的方法,我们研究了一些重要分子离子的光谱,如：CH3CN^＋/CD3CN^＋的电子运动与核振动之间的相互作用（Jahn-Teller效应）.     

Vibrational quasicontinuum of polyatomic molecules: New problems for laser spectroscopy

Generally, the subject of the paper is related to the structure of highly excited vibrational states of polyatomic molecules. The problem is treated in terms of intramolecular vibrational dynamics as well as spectroscopy of vibrational transitions. Theoretical approximations which allow us to calculate spectra starting from dynamics are discussed. A microscopic treatment of spectroscopic relaxation timesT ₁ andT ₂ is given. Also, various experimental approaches to study the problem are outlined including the measurements of stochasticity onset in molecules.     

Selective excitation of vibrational modes of polyatomic molecule

Mode-selective dynamics of triatomic molecule in the electronic ground state under continuous wave laser pulse is investigated for the discrete vibrational bound states. A non-perturbative approach has been used to analyse the vibrational couplings and dynamics of the molecule.     

非晶态物质原子局域连接度与弛豫动力学

非晶态物质的本质及形成过程是凝聚态物理领域最困难也是最有趣的问题之一.非晶形成过程在原子结构上不会衍生出人们在传统晶体结构里所熟悉的长程有序性,因此对于此类在自然界中广泛存在的物质形态,至今还没有有效的实验表征手段和理论研究方法.非晶态物质的原子结构及其构效关系的研究是凝聚态物理和材料科学等众多研究领域所关注的热点问题之一.随着对非晶态物质物性研究的深入,人们逐渐意识到非晶态物质中原子中程序对系统性质的重要影响,建立以中程序为基础的结构-动力学关系对于理解玻璃及玻璃转变的本质起着重要的作用.本文简要综述了基于图论提出的原子局域连接度这一新的结构序参量在液体和玻璃的结构及构效关系研究中的应用.新的结构序参量从过去侧重于关注局域原子团簇的种类和分布,转移到更加关注某一类具有特殊对称性的原子的空间连接情况,即更多地尝试从原子中程序的角度来建立非晶态物质中的构效关系.新的研究结果表明,局域连接度可与非晶态物质中原子的短时或长时动力学行为、输运方式、以及振动模态等一系列物理性质建立联系.     

Global dynamical analysis of vibrational manifolds of HOCl and HOBr under anharmonicity and Fermi resonance: the dynamical potential approach

The vibrational dynamics of HOCl and HOBr between bending and OCl/OBr stretching coordinates with anharmonicity and Fermi coupling is studied with the classical dynamical potential approach. The quantal vibrational dynamics is mostly mapped out by the classical nonlinear variables such as fixed points, except for the state energies, which are quantized. This approach is global in the sense that the focus is on a set of levels instead of individual ones. The dynamics of HOBr is demonstrated to be less complicated. The localized modes along the OCl/OBr stretching coordinates are also shown to have O--Br bonds more prone to dissociation.     

Spectrally dispersed femtosecond CARS investigation of vibrational characteristics in ethanol

Spectrally dispersed femtosecond time‐resolved coherent anti‐Stokes Raman spectroscopy is applied to study the ultrafast vibrational dynamics in ethanol at room temperature. The anti‐Stokes intensities were monitored as a function of delay time and wavenumber. By simply changing the timing of the laser pulses, the vibrational dynamics between the excited Raman transitions in ethanol molecules can be tracked and detected. Copyright © 2014 John Wiley & Sons, Ltd.     

Phonon-assisted excitation energy transfer in photosynthetic systems

The phonon-assisted process of energy transfer aiming at exploring the newly emerging frontier between biology and physics is an issue of central interest.This article shows the important role of the intramolecular vibrational modes for excitation energy transfer in the photosynthetic systems.Based on a dimer system consisting of a donor and an acceptor modeled by two two-level systems,in which one of them is coupled to a high-energy vibrational mode,we derive an effective Hamiltonian describing the vibration-assisted coherent energy transfer process in the polaron frame.The effective Hamiltonian reveals in the case that the vibrational mode dynamically matches the energy detuning between the donor and the acceptor,the original detuned energy transfer becomes resonant energy transfer.In addition,the population dynamics and coherence dynamics of the dimer system with and without vibration-assistance are investigated numerically.It is found that,the energy transfer efficiency and the transfer time depend heavily on the interaction strength of the donor and the high-energy vibrational mode,as well as the vibrational frequency.The numerical results also indicate that the initial state and dissipation rate of the vibrational mode have little influence on the dynamics of the dimer system.Results obtained in this article are not only helpful to understand the natural photosynthesis,but also offer an optimal design principle for artificial photosynthesis.     

Vibrational relaxation dynamics in transient grating spectroscopy studied by rate equations based on time-dependent correlation function

A modified model, a set of rate equations based on time-dependent correlation function, is used to study vibrational relaxation dynamics in transient grating spectroscopy. The dephasing, the population dynamics, and the vibrational coherence concerning two vibrational states are observed respectively in organic dye IR780 perchlorate molecules doped polyvinyl alcohol matrix. The result shows that in addition to the information concerning system-environment interac- tion and vibrational coherence, the vibrational energy transfer can be described by this modified model.     

Infrared spectroscopy of particulate matter: between molecular clusters and bulk

The present contribution focuses on the vibrational dynamics of large molecular aggregates with sizes ranging from the subnanometre to the micrometre region. These aggregates or particles bridge the gap between molecular clusters and bulk matter. Depending on the kind of intermolecular interactions, the vibrational dynamics of the particles can be strongly influenced by intrinsic particle properties such as size, shape, or surface area. Such phenomena are discussed for several examples. In contrast, for some substances the vibrational spectra are mainly governed by local effects, i.e. by the interaction of neighboring molecules. The comparison of the experimental results with different model calculations leads to a deeper insight into the microscopic origin of the characteristic patterns observed. The vibrational dynamics are studied by Fourier transform infrared spectroscopy. In addition, the particle properties are characterized by microscopy and measurements of the size distribution. Four different particle generation methods are discussed. It is shown that the methods of generation can even influence the chemical composition of the particles.     

氢分子离子库仑爆炸中核动力学的理论研究

在非Born-Oppenheimer近似条件下, 通过数值求解一维含时薛定谔方程, 理论模拟了氢分子离子处于不同初始核振动态的库仑爆炸核动能释放谱并探究了氢分子离子发生库仑爆炸时的核动力学. 数值结果表明: 初始核振动态的选取在很大程度上影响着氢分子离子发生库仑爆炸时的核动力学,且高低振动态的选取分别对其核动力学的影响呈现出相反的变化趋势.