HN3分子在190-248 nm的紫外光分解动力学

利用氢原子里德堡态飞行时间谱技术研究HN3分子在紫外光(190?248 nm)光照射下的H+N3通道的光解动力学结果．通过测量H+N3通道的产物平动能分布以及产物的角分布，得到了在不同波长光解下N3产物分子的振动态分布． 实验结果表明， 在大于225 nm时，HN3分子主要是通过一个排斥态解离的．而在低于225 nm时，有一个慢的通道从220 nm 开始出现．这一新的解离通道是一个闭环产生环状N3产物的通道．当光解能量增加时，这一新通道相对的变得越来越重要．     

CH3S自由基eA2A1态的近紫外光解动力学: 氢原子产物通道

实验研究射流冷却CH3S自由基eA2A1态在352 nm的光解动力学． 应用氢原子产额谱和光碎片平动能谱方法第一次直接观察到氢原子产物解离通道．CH3S自由基eA2A1态2132振动能级解离为H和H2CS产物．H+H2CS产物平动能释放较小，平动能峰值接近33.4 kJ/mol．氢原子产物角分布是各向同性．H+H2CS产物是经eA2A1激发态向X2E基态内转变，紧接着在基态势能面上解离产生．     

1-戊基的紫外光解动力学（英文）

利用高里德堡态氢原子飞行时间(HRTOF)探测技术,研究了1-戊基在解离光波长范围236～254 nm下的光解离动力学过程.1-戊基的氢原子光解碎片谱在245 nm左右有一与乙基和正丙基在2p_z→3s跃迁下类似的峰.H原子和C_5H_(10)产物的平动能分布谱中存在双峰,分别位于5 kcal/mol(低平动能)和50 kcal/mol(高平动能)附近.在碳氢键断裂过程中,有30%的过剩能量转换为氢原子和对应解离碎片的平动能(高平动能产物(f_v=0.58,低平动能产物     

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．     

甲醇在TiO2(110)表面光催化氧化的波长相关性

用程序升温脱附谱的方法研究了甲醇在TiO₂(110)表面光催化氧化的波长相关性．对于不同波长的激发光,甲醇光催化解离的产物相似,都是在光照的过程中通过O-H键和C-H键的断裂形成甲醛,解离出的氢原子转移到相邻的两配位的桥氧原子(O_b)上形成O_bH．但是反应速率与激发光波长强烈相关．在360 nm光照下,甲醇的反应速率是400 nm光照时的4.8倍．这与以前使用时间分辨的飞秒激光吸收光谱测量的结果是一致的,他们认为近带隙激发和过带隙激发产生的电荷相比,前者的复合速率要远快于后者．     

邻碘甲苯分子光解动力学的飞秒时间分辨质谱研究

利用飞秒时间分辨质谱技术研究了邻碘甲苯分子在266 nm激发下的光解动力学. 光解产物碎片通过800 nm强激光场下的多光子电离实现探测. 拟合光解产物C₇H₇自由基和I原子随泵浦-探测延迟时间变化的信号,得到解离时间为38±50 fs,它反映的是266 nm同时激发nσ^*和ππ^*态后C-I键的平均解离时间. 此外,还利用基态碘原子的共振波长298.23 nm作为探测光,通过共振增强多光子电离方法对解离生成的基态碘原子进行了选择性探测. 拟合I⁺随泵浦-探测延迟时间变化的信号,得到解离时间为40±50 fs,这与通过800 nm多光子电离得到的解离时间一致,表明解离生成的主要产物是基态碘原子.     

紫外光解动力学DNCO+hv→D+NCO: 两个竞争解离通道

本文利用D原子里德堡态时间飞行谱研究了DNCO分子在波长200∽235 nm范围的光解动力学. 实验测量了产物的平动能分布和空间角分布. 在210∽235 nm光解离下,观测到接近统计分布和各向同性的产物,该产物有可能来自从S₁势能面内转换到S₀势能面,然后在S₀势能面上解离. 在更短的解离波长下,除了统计分布的产物,另外一种分布的产物出现在高平动能的地方,具有很高的各向异性,该产物来自从S₁势能面上的直接解离. 相比较HNCO的解离结果,DNCO直接解离通道出现在更高的激发能量. 通过对NCO产物内能态的归属,发现NCO产物主要是弯曲振动激发和适当的伸缩振动激}.     

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.     

Br2+分子离子[1+1]双光子解离动力学

本文利用最近研制的低温离子阱-离子速度成像谱仪在冷离子束中研究了同位素质量分辨的⁷⁹Br₂⁺分子离子的[1+1]双光子激光解离动力学. 借助其1⁴Σ^-_u,3/2态为中间态使⁷⁹Br₂⁺共振吸收两个光子至4∽5 eV区域的高激发态并发生解离. 利用离子速度成像技术获得了光解产物⁷⁹Br⁺的二维速度分布和平动能释放谱. 通过平动能释放谱确定了不同解离能量处量子态分辨的解离产物通道分支比. 光碎片产物的角分布表明⁷⁹Br₂⁺分子离子的双光子解离是1⁴Σ^-_u,3/2态的ΔΩ=0平行跃迁至一个Ω=3/2高解离态发生的. 由于分子激发态中的强自旋-轨道耦合作用,高激发的四重态很可能参与到实验观测的光解过程.     

OCS分子在里德堡F态的真空紫外光解动力学：S(3PJ=2,1,0)产物通道

本文利用可调谐真空紫外光源和时间切片离子速度成像技术研究了OCS分子的真空紫外光解动力学. 在对应OCS里德堡F态的五个光解波长下(133.26 nm∽139.96 nm)实验采集了S(³P_J=2,1,0)产物的离子影像,从中发现了两个解离通道：S(³P_J=2,1,0)+CO(X¹Σ⁺)和S(³P_J=2,1,0)+CO(A³π),其中前者为主要通道. 离子影像中CO产物的振动结构可部分分辨. 从离子影像中提取出了S(³P_J=2,1,0)+CO(X¹Σ⁺)通道的产物总平动能分布、各向异性参数和CO振动态分支比等信息. 发现了对应OCS在F态的几个低振动态下光解的产物各向异性参数取负值,而对应F态的几个高振动态下光解产物的各向异性参数为正值. 另外,同一光解波长下三种S产物S(³P₂)、S(³P₁)和S(³P₀)的各向异性参数也不相同. 经分析,这些现象可能来源于激发区域的其它不同对称性的电子态的贡献,从而导致解离过程中同时存在平行解离和垂直解离. 本工作有利于进一步理解OCS真空紫外光解中的非绝热耦合作用.     

Differential Raman cross section of dimethyl sulfide

Biogenic sulfur compounds such as dimethyl sulfide (DMS) are important contributors to the global carbon cycle. The differential Raman cross section of DMS relative to the nitrogen fundamental, σ_DMS, has been measured at several excitation wavelengths in order to assess the applicability of Raman spectroscopy for the direct quantitative measurement of this compound. At 488 nm, σ_DMS for the ν₆ carbon–sulfur stretching mode was found to be 4.9 ± 1.6, while for the ν₂ carbon–hydrogen stretching mode it was 2.8 ± 0.9. Using, KrF laser excitation, values for σ_DMS could be measured simultaneously at two excitation wavelengths, 248.32 and 248.69 nm. The average values of σ_DMS for 248‐nm excitation based on measurements at these two excitation wavelengths were 3.5 ± 1.4 for the carbon–sulfur stretching mode and 4.6 ± 0.6 for the carbon–hydrogen stretching mode. The results indicate that no significant resonance enhancement of σ_DMS for either mode occurs, although they show some slight enhancement of the cross section for the ν₂ band (C H stretching mode). It was concluded that the measured values of σ_DMS are high enough to allow the quantitative detection of DMS at the millimolar level. Copyright © 2010 John Wiley & Sons, Ltd.     

UV excimer radiation from dielectric-barrier discharges

Dielectric-barrier (silent) discharges are ideally suited for efficient excitation of high-intensity UV radiation from excimers. The molecular continuum of xenon at 172 nm could be obtained with an efficiency of close to 10%. Model calculations for excimer formation and UV efficiencies in such discharges are presented. The possibility of obtaining many other wavelengths (e.g. KrF^* at 248 nm and XeCl^* at 308 nm) and the variety of conceivable geometries (plane or cylindrical) makes this new UV source an attractive choice for many photophysical and photochemical applications.     

Coherence gating in optical heterodyne detection measurements of scattering and absorption in highly scattering media

Laser-Induced Fluorescence (LIF) from the S₁ state of acetone and 3-pentanone was studied as a function of temperature and pressure using excitation at 248 nm. Additionally, LIF of 3-pentanone was investigated using 277 and 312 nm excitation. Added gases were synthetic air, O₂, and N₂ respectively, in the range 0–50 bar. At 383 K and for excitation at 248 nm, all the chosen collision partners gave an initial enhancement in fluorescence intensity with added gas pressure. Thereafter, the signal intensity remained constant for N₂ but decreased markedly for O₂. For synthetic air, only a small decrease occurred beyond 25 bar. At longer excitation wavelengths (277 and 312 nm), the corresponding initial rise in signal with synthetic air pressure was less than that for 248 nm. The temperature dependence of the fluorescence intensity was determined in the range 383–640 K at a constant pressure of 1 bar synthetic air. For 248 nm excitation, a marked fall in the fluorescence signal was observed, whereas for 277 nm excitation the corresponding decrease was only half as strong. By contrast, exciting 3-pentanone at 312 nm, the signal intensity increased markedly in the same temperature range. These results are consistent with the observation of a red shift of the absorption spectra (9 nm) over this temperature range. Essentially, the same temperature dependence was obtained at 10 and 20 bar pressure of synthetic air. It is demonstrated that temperatures can be determined from the relative fluorescence intensities following excitation of 3-pentanone at 248 and 312 nm, respectively. This new approach could be of interest as a non-intrusive thermometry method, e.g., for the compression phase in combustion engines.     

杂环分子-吗啉在同步辐射真空紫外光下的光电离解离研究

本文采用同步辐射真空紫外光电离质谱法和理论计算方法,研究了吗啉单体的光电离、解离及随后的裂解反应.实验测得吗啉单体的垂直电离能为8.37 eV(±0.05),与理论计算值8.41 eV相当吻合.实验观察到荷质比为86、57和29的吗啉碎片离子.实验和理论结果表明:荷质比为86的碎片是通过失去氢原子而产生的,而荷质比为57的碎片是通过开环消除CH_2O而形成的;荷质比为29的碎片是通过消除C_2H_4从碎片离子(C_3H_7N)~+(m/z=57)进一步解离而产生的.这一发现为研究脂肪族化合物的光损伤提供了有价值的见解,可能被转化为活细胞和其他生物系统.     

225∽260 nm波段溴化氰光解动力学系统性研究

本文报道了在自行搭建的时间切片离子速度成像装置上进行的225∽260 nm波段内溴化氰光解动力学的研究. 在该波段内选取了若干溴原子(²P_3/2或²P_1/2)的共振线对产物溴原子的共振电离并采集其切片影像,得到了光解产物的总平动能谱,进而获得了产物氰基的振转态布居等信息. 本文发现了在Br^*通道,产物氰基的内能激发比Br通道低;Br和Br^*通道产物氰基振动的最高布居分别为v=0和1. 另外,还发现对于Br通道,溴化氰分子在长波处与短波处解离时,氰基产物的振转激发差异很大,这揭示了其显著不同的光解动力学.     

Luminescence of undoped β-Ga2O3 single crystals excited by picosecond X-ray and sub-picosecond UV pulses

Undoped β-Ga₂O₃ single crystals were grown using the floating zone technique under a pressure of 2 atm oxygen. Luminescence spectra of the crystals were measured with steady-state X-ray (<15 keV) and UV (258 nm, 4.8 eV) sources. The X-ray excitation produced a spectrum with a peak at 390 nm (3.2 eV) whereas the UV excited spectrum had a peak at 430 nm (2.9 eV). The luminescence rise and decay were also examined by using picosecond X-ray and sub-picosecond UV pulses. It was found that the X-ray pulse excitation gave a slower rise and a faster decay of the luminescence compared with the UV pulse excitation. These results suggest that X-ray excitation generates high energy electrons, building up luminescent states until those electrons lose their kinetic energies, giving rise to the formation of local hot spots in the gallium oxide crystals.     

Triplet state and phenoxyl radical formation of 3, 4‐methylenedioxy phenol: a combined laser flash photolysis and pulse radiolysis study

Formations of triplet state, molecular cation radical, and phenoxyl radical of 3,4‐methylenedioxy phenol (sesamol, SOH) in organic solvents have been investigated by laser photolysis as well as pulse radiolysis techniques. Photolysis of SOH in cyclohexane has been found to produce both triplet state (λ_max ～ 480 nm) and phenoxyl radical (425–430 nm) of SOH by mono‐photonic processes. However, radical cation (λ_max = 450 nm) and phenoxyl radical of SOH have been observed on radiolysis in cyclohexane. Further, radiolysis of SOH in benzene has been found to produce phenoxyl radical only. Mechanism of phenoxyl radical formation by photo‐excitation of SOH has been studied and triplet energy level of SOH is estimated to lie between 1.85 and 2.64 eV. Copyright © 2007 John Wiley & Sons, Ltd.     

Luminescence kinetics of LiNbO3:Yb3+-Er3+, LiNbO3:Er3+, and LiNbO3:Yb3+ crystals under selective excitations in the impurity subsystem

The results of investigations of luminescent radiations’ kinetic characteristics for LiNbO₃:Yb³⁺-Er³⁺, LiNbO₃:Er³⁺, and LiNbO₃:Yb³⁺ crystals under optical excitations at 532 nm and 1064 nm wavelengths are presented. The shapes and times of rise and damping of luminescent signals at 550 nm, 980 nm and 1555 nm wavelengths under selective excitations in the impurity subsystem of the investigated materials are determined. Comparison of the temporal characteristics of luminescent responses of LiNbO₃ crystals doped separately with Yb³⁺ and Er³⁺ ions with those of the LiNbO₃:Yb³⁺-Er³⁺ crystal allows identifying the contributions from different energy transfer processes of optical excitation taking place in the impurity subsystem of the material.     

Ablation mechanism of PTFE under 157 nm irradiation

We report time- and mass-resolved measurements on neutral particles emitted from polytetrafluoroethylene (PTFE) during exposure to 157-nm laser radiation at fluences where etching is observed. By comparing the time-of-flight signals over a range of masses, we conclude that (CF₂) _N fragments for N=1–6 are emitted directly from the surface in substantial quantities. In contrast, the monomer (N=2) is the principal product during irradiation at 248 nm, where thermal decomposition is important. The time-of-flight signals of all the (CF₂) _N fragments show fast components with kinetic energies on the order of an electron volt. These high kinetic energies are consistent with photochemical scission of the polymer backbone, where a fraction of the excitation energy is delivered to the fragment as kinetic energy. Although clean etching is observed under these conditions, the great majority of the mass removed from the target appears as much larger fragments that do not reach our detector. The nature of this material and its affect on the velocity distribution of the observed (CF₂) _N fragments is discussed.