SF自由基的REMPI光谱：观测到一个新的2§电子态

利用SF6/Ar混合气沿气束方向放电， 产生SF自由基．在306?321 nm范围内扫描激光波长得到SF自由基(2+1) REMPI光谱． 观测到2§?X2|双光子跃迁的５ 个振转谱带， 通过对实验谱分析获得新观测到2§里德堡态的转动常数近似值和振动频率约815 cm?1；同时对2|3=2?X2|3=2跃迁谱带进行了转动分析，转动常数B0v?0.42 cm?1，该谱带对应着(1+2) REMPI机理；对SF自由基电离解离机理也进行了讨论．     

离子速度成像法研究HNCO分子在210 nm的光解动力学

用三维离子速度成像方法研究了HNCO分子在210 nm光解下的光解动力学．得到了光解产物CO在不同转动态的角分布和平动能分布．结果表明，HNCO分子在210 nm光解的主要通道是产生NH(a1￠)+CO(X1§+)的通道；碎片CO具有很高的转动激发，而NH的转动激发很小，约50％可资用能转化为平动能，该通道解离能确定为42738 cm?1；解离各向异性参数ˉ 最小为?0.75，且随着NH转动激发增大．该研究首次实验上证实了HNCO分子的快速、直接解离过程．ˉ值随NH的转动变化可以用经典碰撞模型予以解释．     

亚硝基苯光解过程中的能量配置

利用单光子激光诱导荧光 (LIF)技术 ,测量了亚硝基苯 (C6H5NO)初生态光解碎片NO(X 2 　Πv″=1,2 ,3)的转动光谱 .通过对初生态光解碎片NO(X2 　Π )内能态布居的分析 ,得到了NO(X 2 　Π )的转动温度和相对振动布居比 ,研究了亚硝基苯在 2 6 6nm激光光解过程中的能量配置情况 .与小分子相比 ,大的亚硝基苯分子 ,其光解过程中能量分布很宽 ,涉及到所有自由度 .     

单光子LIF方法研究亚硝基苯266 nm光解动力学

用266nm激光解离亚硝基苯（C6H5NO）产生光解碎片NO,并利用单光子激光诱导荧光（LIF）技术（X^2Ⅱv″=0→A^2∑^+v′=0）测得初生态光解产物NO的振转光谱。根据计算所得的模拟光谱对光解碎片NO（X,v^″＝0）的转动量子数J″进行了归属,得到了量子数最大到J″＝50．5的转动能级的相对布居,这表面光解碎片NO具有较高的转动激发。提出了C6H5NO在266nm下可能的光解机理。     

NO2 在第二电子吸收带的光解

运用单光子激光诱导荧光方法 ,研究了NO2 分子在第二吸收带的光解反应动力学 .首次报道了NO2(B2 B2 态 )光解初生态产物NO自由基的v″ =1,2的转动分布 .发现了NO自由基v″ =1的明显双模式分布 .进而提出了可能有两种竞争机理控制该反应     

Detection of OH Radical in the Photodissociation of p-Aminobenzoic Acid at 266 nm

利用激光诱导荧光光谱方法研究了对氨基苯甲酸在266 nm条件下光解生成的OH自由基的高分辨振转光谱. 研究发现OH自由基几乎处于振动基态并且它的转动布居符合波尔兹曼分布,转动温度可表征为1040±110 K,相对应的转动能为8.78±0.84 kJ/mol.在²Π_3/2和²Π_1/2旋轨耦合态中,前者布居占多数;并且Λ分裂态的Π(A′)态占优. 最后讨论了OH自由基来自对氨基苯甲酸光解可能的解离机理.     

HOBr/DOBr态到态光解动力学的量子波包研究

本文基于高水平的多参考组态相互作用计算，报导了HOBr的最低三个单重态的三维势能面. 并且对该分子的光解离过程用实波包传播的方法进行了量子动力学研究，不仅计算结果得到了吸收光谱，而且还产生了光解产物的内态和角度分布. 结果与在紫外区域测得的HOBr的总吸收截面定量吻合，并很好的重现了实验上在266 nm处观察到的振动冷和转动热的光解OH/OD产物. 此外，预测了OH/OD的反冲各向异性参数接近平行跃迁的极限值，表明在266 nm处从基态(1¹A'')到2¹A''态的面内跃迁是一个快速的解离过程. 这与实验上从测量转动取向得出的结论一致. 然而，想要实现与实验上的定量一致，还需要考虑自旋和电子角动量的影响.     

撞击诱导硝基甲烷分子第一步分解反应的动力学计算

本文基于分子温度与压强的关系,计算在不同压强下基态和最低三态硝基甲烷的分子温度,对应计算其沿着CN键裂解反应的热化学和动力学参数.发现基态的硝基甲烷沿着CN键的分解反应是吸热反应,不具自发性,反应转换温度为1550.2 K,平衡常数在80-1202 K温度范围内很低.最低三态的硝基甲烷沿着CN键的裂解是放热反应,反应的Gibbs自由能在80-2558.5 K范围内为负,有好的自发性,且反应较为彻底.298.15-2558.5 K温度范围内反应活化能随着温度的升高而改变,使反应速率随着温度的升高而急剧增大.对应硝基甲烷爆压15 GPa,其分子温度为4617.6 K,该温度下三态分子分解反应的反应速率为1.088×10~8cm~3·mol~(-1)·s~(-1).推算硝基甲烷沿着CN键分解反应混合物的终态温度,当混合物为硝基、甲基和基态的硝基甲烷分子时,反应的终温为1611.37 K,等效能为1676.47 cm~(-1).当混合物为硝基、甲基、基态和最低三态的硝基甲烷分子时,反应的终温为1184.79 K,等效能为1232.65 cm~(-1).两种情况下终态等效能都足以维持硝基甲烷分子沿C-N键裂解反应的发生.这个能量也足以导致混合物中的NO_2分解为NO和O,这与实验检测的结论相一致.     

Ar(3P0,2)+NH3初生态产物NH2(2A1)的内态分布

首次报告了在分子束条件下,研究Ar(3P0,2)+NH3碰撞解离反应·利用单光子计数方法进行测量,获得了部分转动分辨的初生态产物NH2(2A1)→（2B1）发射谱,并详细地进行了标识·发现主要为（0,v 2',0)→（0,0,0）跃迁（v2'≤5,K'a≤6,J'≤10)。通过对部分分辨较好的光谱范围进行了模拟,得到反应生成的NH2(2A1,v2'=2,k'a =1)态绕b/c轴的转动温度为1050K,高于母体分子NH3的转动温度300K。由亚稳态碰撞传能电子交换机理认为这是由于碰撞对手Ar和母体NH3分离时反冲作用的结果。碰撞传能解离机理和光解过程不同,后者仅观察到轴的转动激发。     

Photodissociation Dynamics of Methanol and Ethanol at 157 nm

利用氢原子里德堡时间飞行谱技术研究了超音速喷射分子束CH3OH和C2H5OH在157 nm的光解动力学,得到了氢原子产物的时间飞行谱．通过对谱图的拟合揭示出三个氢原子产物通道：OH上的氢原子脱落、CH3(C2H5)上的氢原子脱落和CH3O(C2H5O)的二次解离． 从得到的产物通道相对分支比可以知道CH3O的二次解离过程比C2H5O更明显．CH3OH解离的产物平均角分布各向异性参数β≈-0.3, 显示出跃迁偶极距接近垂直于C-O-H平面．C2H5OH解离的产物β≈-0.4,表明C2H5OH有更长的转动周期． 实验结果显示两个系统都经历了从3px到3s势能面的快速内转换, 然后在3s势能面上解离．CH3O+H产物平动能分布显示出CH3O的伞形振动激发或者CH3的摇摆振动激发,而C2H5O+H产物平动能分布没有振动态分辨．     

乙醛光解动力学的离子速度成像

利用时间切片离子速度成像技术在275～321 nm能量范围内重新研究了乙醛自由基通道CH₃+HCO的光解动力学. 通过共振增强多光子电离的方法探测甲基碎片. 对甲基的伞形振动基态和激发态(v₂=0和1)进行了影像探测. 乙醛通过T₁电子态系间窜越到S₁电子态的解离产物具有很高的动能释放和很低的内能激发,碎片的振动能和转动能随激发能量的增加而增加. 乙醛T₁电子态的势垒高度经测量高于基电子态3.881±0.006 eV.     

Microwave spectrum,dipole moment,and structure of 3-aminopropanol

The microwave spectra of 3-aminopropanol and three of its deuterium substituted isotopic species have been investigated in the 26.5 to 40 GHz frequency region. The rotational spectrum of only one conformer has been assigned in which presumably a hydrogen bond of the OH---N type exists. The rotational spectra of a number of excited vibrational states have been observed and assignments made for some of these excited states. The average intensity ratio for the rotational transitions between the ground and excited vibrational states indicates that the first excited state is about 120 cm^?1 above the ground state.and the next higher state is roughly 200 cm^?1 above the ground vibrational state. The dipole moment was determined from the Stark effect measurements to be 3.13 ± 0.04 D with its principal axes components as |μ_a| = 2.88 ± 0.03 D, |μ_b| = 1.23 ± 0.04 D and |μ_c| = 0.06 ± 0.01 D. The possibility of another conformer where the hydrogen bond could be of NH---O type was explored, but the spectra of such a conformer could not be identified.     

Conformation and dipole moment of tetrahydropyran-4-one by microwave spectroscopy

The microwave spectrum of tetrahydropyran-4-one has been studied in the frequency region 18 to 40 GHz. The rotational constants for the ground state and nine vibrationally excited states have been derived by fitting a-type R-branch transitions. The rotational constants for the ground state are (in MHz) A = 4566.882 ± 0.033, B = 2538.316 ± 0.003, C = 1805.878 ± 0.004. From information obtained from the gas-phase far-infrared spectrum and relative intensity measurements, these excited states are estimated to be ～ 100 cm^?1 above the ground state for the first excited state of the ring-bending and ～ 185 cm^?1 for the first excited state of the ring-twisting mode. Stark displacement measurements were made for several transitions and the dipole moment components determined by least-squares fitting of the displacements: (in Debye) |μ_a| = 1.693 (0.001), |μ_b| = 0.0, |μ_c| = 0.300 (0.013) yielding a total dipole moment μ_tot = 1.720 (0.003). A model calculation to reproduce the rotational parameters indicates that the data are consistent with the chair conformation.     

水分子高激发态的绝热势能面与光解机制

本文在从头算icMRCI+Q水平上,发展了水分子的基态和九个激发态?、?、B、C、D、D''、D''、?''和F的全维绝热势能面. 势能面的拟合采用了高斯过程回归并结合置换不变多项式方法. 通过选择大的活动空间与添加额外弥散函数的基组来准确描述这些里德堡状态,计算得到的垂直激发能和平衡构型与先前的理论与实验值十分吻合. 相对于前三个被广泛研究的低能量电子态,对高激发态光解的理论与实验研究仍然十分有限. 本文研究了水在真空紫外光解过程中涉及到的高激发态的全部三个解离通道. 特别是基于新发展的势能面,首次清晰地阐明了D-E''、E''-F、?-?和?-C电子态之间的锥形交叉等信息,文中详细讨论了这些电子激发态的非绝热解离途径,为阐明这些高里德堡态的光解离机制提供了帮助.     

Measurement of the Raman polarizability anisotropy for the v = 1 pure rotational Raman transition in H 2 by rotational Raman spectroscopy

A combination of stimulated Raman pumping and rotational Raman spectroscopy is used to accomplish the first measurement of the polarizability anisotropy γ_11,13 (355 nm) for the S₁₁ (1) transition in molecular hydrogen H₂. Saturation of the Q₀₁(1) transition connecting the |X¹ Σ⁺ _g, v = 0, J = 1 > state to the |X¹ Σ⁺ _g, v = 1, J = 1 > state in H₂ by stimulated Raman pumping is the critical element in this experiment. The observed intensities of the rotational Raman lines for these states allow an estimate of γ_11,13 (355 nm) as 0.358 ± 0.004 ų. A comparison of this value to that obtained from fundamental ab initio calculations in H₂ also is possible for the first time.     

Energy transfer in the A2Σ+ state of OH following v’ = 1 excitation in a low pressure CH4/O2-flame

2 Σ⁺(v’=1) level of OH. Measurements were performed in a laminar premixed flame at 10 Torr total pressure. The low pressure allowed the spatial variation of the effective quenching rate to be determined through the flame front. In addition, the dependence of the quenching rate on rotational quantum number was measured by exciting a series of rotational lines in the range N’=0–16. The results show that the total quenching rate decreases only 17% through the flame front, in the region where OH can be detected. Nevertheless, the absolute value of the quenching rate Q is required if absolute concentrations are to be determined from LIF-signals. The variation both of Q and of the rotational relaxation rate with excited rotational quantum state must be known for quantification of LIF-temperature measurements via the Boltzmann relation. Finally, the rotational and vibrational energy transfer (RET, VET), was investigated by recording the spectrally and temporally resolved fluorescence. For all excited rotational lines, efficient RET to neighbouring rotational states was observed, but only very little VET. Total RET rates were determined from the difference between the time-resolved broadband (total fluorescence) and narrowband (fluorescence from the laser excited level) curves. The experimental results were compared with simulations using a dynamic model, which describes the energy transfer for flame conditions. With the available input data (temperature, major species concentrations and collision-partner specific RET cross sections), good agreement was obtained. Received: 3 February 1997/Revised version: 3 September 1997     

State selective predissociation spectroscopy of hydrogen chloride ions (HCl+) via the A2Σ+ ← X2Π3/2 transition

The photodissociation of hydrogen chloride ions (HCl⁺) has been investigated through the A²Σ⁺ (ν′ = 6, 7 and 8) ← X ²Π_3/2 (ν″ = 0) transition. The spectra reveal that state selective photodissociation with complete resolution of the spin, orbital, and rotational angular momentum is possible in the A ²Σ⁺ (ν′ = 6) state. The analysis of these spectra yields the rotational and the spin-rotation coupling constant of the A ²Σ⁺ (ν′ = 6) state. The lifetime of HCl⁺ decreases significantly with increasing vibrational excitation in the ²Σ⁺ state. Within the experimental error limits no J dependence of the lifetime is observerd. The state selective photodissociation of the HCl⁺ ions is also shown to be a very sensitive probe for unexpected parity transitions in the 2 + 1 REMPI formation of the HCl⁺ ions in the X 2Π_3/2 (ν″ = 0) state.     

The microwave spectrum,dipole moment,and conformation of 3-oxabicyclo(3.1.0.)hexane

The microwave spectrum of 3-oxabicyclo(3.1.0.)hexane has been studied in the range 26.5–40 GHz (R-band) with a Hewlett Packard Model 8400 spectrometer. Both a and c-type R-branch transitions were used to derive the rotational constants for the ground state and first two excited states of the ring-puckering mode. The data are consistent with a single stable conformation, in agreement with a previous far-infrared study (1) and this is shown to be the boat conformation, as was the case with the similar molecules cyclopentene oxide (2, 3) (6-oxabicyclo(3.1.0.)hexane) and 3,6-dioxabicyclo(3.1.0.)hexane (1, 4). The rotational constants for the ground state are (in MHz) A = 6038.06; B = 4432.47; C = 3303.43 yielding κ = ? 0.174268. The electric dipole moment components of the ground state (in Debye units) are |μ_a| = 1.36 ± 0.02; |μ_c| = 1.03 ± 0.02 yielding a total dipole moment μ = 1.71 ± 0.03.     

Energy partitioning in photodissociation and photosensitization

The molecular dynamics of photodissociation and of electronic vibrational/translational energy transfer have been investigated in terms of an impulsive ‘half-collision’ model, modified to accommodate the possibility of changes in the potential energy functions (force constants) of the separating fragments. The model, which is suitable for any system which is suddenly prepared on a repulsive potential energy surface (e.g. following electronic excitation or radiationless transition), has been applied to the quenching of Hg(6³P₁) by CO and NO and to the photodissociation of ICN. Experimental data and alternative theoretical treatments are available for each of these systems. The new model is able to achieve a remarkable agreement with observation in the Hg/CO and NO systems by assuming the intermediate formation of a Hg(6³P₀) - CO or NO complex in which the C-O or N-O bond order increases by ～ 0·6. Model calculations for the quenching of Cd and Zn(³P₀) suggest that the distributions over final states would be very similar to that for Hg(³P₀).

A re-appraisal of the near U.V. photo-dissociation of ICN indicates that CN radicals should be formed preferentially in the òπ electronic state; those observed in the ground state should be vibrationally excited whether they appear as primary photo-products or not.

In general, changes in the equilibrium bond length of the molecular fragment as the system transfers onto the repulsive potential surface, are crucial in determining both the level of vibrational excitation and the detailed distribution over final states. When the molecular fragment has a large force constant the ‘steepness’ of the potential surface is relatively unimportant.