Parameters of Isotope Shifts for 2s2p~(3,1)P_1→ 2s~(2 1)S_0 Transitions in Heavy Be-Like Ions

The field shift and mass shift parameters of the 2s2p~(3,1)P_1→ 2s~(2 1)S_0 transitions in Be-like ions(70 ≤ Z≤ 92)are calculated using the multi-configuration Dirac–Hartree–Fock and the relativistic configuration interaction methods with the inclusion of the Breit interaction and the leading QED corrections. We find that the mass shift parameters of these two transitions do not change monotonously along the isoelectronic sequence in the high-Z range due to the relativistic nuclear recoil effects. A minimum value exists for the specific mass shift parameters around Z= 80, especially for the 2s2p~(3,1)P_1→ 2s~(2 1)S_0 transition. In addition, the field shifts and mass shifts of these two transitions are estimated using an empirical formula, and their contributions are compared along the isoelectronic sequence.     

Oscillator strength measurements of the 4s5s 3S1 → 4snp 3Po2 Rydberg transitions of zinc

In the present experimental work, oscillator strengths of the 4s5s ³S₁ → 4snp ³P^o₂ (18?≤?n?≤?53) Rydberg transitions of zinc are reported. The stepwise laser excitation from the ground state 4s^{2 1}S₀ was achieved using three dye laser beams simultaneously pumped by the second (532?nm) and third (355?nm) harmonics of a Q-switched Nd: YAG (Neodymium-doped yttrium aluminum garnet) laser. The vapor containment and detection system was a single wire thermionic diode ion detector operating in space charge limited mode. A trend of the above-mentioned f-values from n?=?18 to 53 versus the principle quantum number n has been presented. Furthermore, continuity has been verified between the discrete f-values and the oscillator strength density at the threshold.     

Magnetooptical Spectroscopy of the 5D4 → 7F5 Radiative Transition of the Non-Kramers Tb3+ Ion in an Yttrium-Aluminum Garnet

Spectra of luminescence and magnetic circular polarization of luminescence corresponding to the ⁵ D ₄ ⁷ F ₅ radiative transition of the Tb³⁺ ion in an yttrium-aluminum garnet are studied experimentally. In the context of crystalline field theory, the energy spectrum of the ⁷ F ₅ multiplet of the Tb³⁺ ion in the garnet is calculated. The structure of internal energy levels of the ⁷ F ₅ multiplet of the Tb³⁺ ion is refined based on a comparison of the calculated results with the experimental data, and the diagram of magnetooptically active radiating transitions between ⁵ D ₄ and ⁷ F ₅ multiplet energy sublevels is constructed.     

Effects of the vibrational and rotational excitation of reagent on the stereodynamics of the reaction S（3P） + H2→ SH + H

Quasiclassical trajectory （QCT） calculations are first carried out to study the stereodynamics of the S （3p） ＋ H2 → SH ＋ H reaction based on the ab initio 13Atr potential energy surface （PES） （Lii etal. 2012 J. Chem. Phys. 136 094308）. The QCT-calculated reaction probabilities and cross sections for the S ＋ H2 （v = 0, j = 0） reaction are in good agreement with the previous quantum mechanics （QM） results. The vector properties including the alignment, orientation, and polarization- dependent differential cross sections （PDDCSs） of the product SH are presented at a collision energy of 1.8 eV. The effects of the vibrational and rotational excitations of reagent on the stereodynamics are also investigated and discussed in the present work. The calculated QCT results indicate that the vibrational and rotational excitations of reagent play an important role in determining the stereodynamic properties of the title reaction.     

High resolution spectroscopy of the transition 5d2D3/2→6p2P 3 2/0 in a fast Ba+ ion beam

Using the “velocity bunching” effect occurring in beam direction of a fast ion beam the hyperfine structure of the Ba II transition 5d²D_3/2→6p²P ₃ ^2/0 has been investigated by means of a laser absorption experiment. From a mass separated¹³⁷Ba⁺ beam we have obtained hyperfine dipole and quadrupole splitting factors A and B and from a not mass separated Ba⁺ beam isotope shift data as well as A and B values. The results are A(5d²D_3/2) =5.696(24) mK, A(6p²P ₃ ^2/0 )=3.759(27) mK, B(5d²D_3/2)=1.01(4) mK, B(6p²P ₃ ^2/0 ) =2.07(4) mK. Values for the isotope shifts are given.     

Energy-Pooling Collisions in Rubidium： 5P3/2 ＋ 5P3/2 → 5S ＋ （nl = 5D, 7S）

We experimentally study rubidium energy pooling collisions of Rb（SP3/2） ＋ Rb（5P3/2） → Rb（5S1/2） ＋ Rb （nlJ = 5DJ, 7S1/2） at low densities in a cell using diode laser excitation. The excited-atom density and spatial distribution are mapped by monitoring the absorption of a counterpropagating single-mode diode laser beam, tuned to the 5P3/2 → 7S1/2 transition, which could be translated parallel to the pump beam. The excited atom densities are combined with measured fluorescence ratios to determine cross sections for the rubidium energy pooling process. The cross sections for nlJ being 5D5/2, 5D3/2, and 7S1/2 are （1.32±0.59）×10^-14, （1.18±0.53）×10^-14 and （3.21±1.44）×10^-15cm^2, respectively.     

SrI 5s^2 ^1S0—5s4d^1D2,5s^2^1S0—5s6d^1D2单光子电四极 …

用染料激光来激发Ｓｒ原子，首次在实验上发现较强的ＳｒＩ５ｓ＾２＾１Ｓ０－５ｓ４ｄ＾１Ｄ２，５ｓ＾２１Ｓ０－５ｓ６ｄ＾１Ｄ２单光子电四极矩Ｅ２共振跃迁离子信号，并对５ｓ＾２１Ｓ０－５ｓ６ｄ＾１Ｄ２共振离子时，伴随出现的前向相干辐射进行了判断与分析。     

Stereodynamics of the reactions: F+H_2/HD/HT→FH+H/D/T

Among many kinds of ways to study the properties of atom and molecule collision, the quasi-classical trajectory(QCT) method is an effective one to investigate the molecular reaction dynamics. QCT calculations have been carried out to investigate the stereodynamics of the reactions F + H2/HD/HT→FH + H/D/T, which proceed on the lowest-lying electronic states of the FH2 system based on the potential energy surface(PES) of the 12A' FH2 ground state. Although the QCT method cannot describe all quantum effects in the process of the reaction, it has unique advantages when facing a three-atoms system or complicated polyatomic systems. Differential cross sections(DCSs) and three angle distribution functions P(θr), P(φr), P(θr, φr) on the PES at the collision of 2.74 kcal/mol have been investigated. The isotope effect becomes more obvious with the reagent molecule H2 turning into HD and HT. P(θr, φr), as the joint probability density function of both polar angles θr and φr, can reflect the properties of three-dimensional dynamic more intuitively.     

D+CD4→CD3+D2反应的量子含时动力学研究

运用半刚体振动转子靶(semirigid vibrating rotor target)模型,利用含时波包法(TDWP method),对反应D+CD4→CD3+D2进行了量子含时动力学研究与计算.反应几率随平动能的变化图象,呈现出显著的量子共振特性.并通过对v=0时,j=0,1,2的反应几率以及j=0时,v=0,1的反应几率的计算,对该反应的空间效应进行了研究与分析.     

D+CD4→CD3+D2反应的四维量子散射计算

运用约化维数量子动力学理论 ,利用含时波包法 ,对反应D +CD4 →CD3+D2 进行了四维量子散射计算 .将反应多原子CD4 看作双原子D—CD3,反应D +CD4 →CD3+D2 看作单原子 双原子反应 ,把体系的反应简化为四维散射问题 .波函数的传播采用分裂算符法 ,为避免格点边界处含时波函数的边界反射 ,采用了光学吸收势法 ,在格点边界处引入光学势 ,消除边界反射 .根据CD4 分子的C3v对称性 ,选取了Jordan和Gilbert提出的半经验势能面 .计算结果表明 ,反应概率随平动能的变化图像 ,呈现出显著的量子共振特性 ,这是很多提取反应的共同特征 .而不同振动态下的反应概率随平动能的变化表明 ,随振动量子数的增大 ,反应概率有明显提高 ,且反应阈能明显降低 ,这说明反应分子的振动能对分子的碰撞反应有重要贡献 .而对基态和第一振动激发态时散射截面的计算 ,也证明了这一结论 .同时 ,还分别通过计算量子数j,k ,m对反应概率的影响 ,对该反应的空间取向效应进行了研究 ,并与H +CH4→CH3+H2 反应进行了比较 .     

Hyperfine structures and isotope shifts of the 5d 4 D 7/2→6p 4 P 5/2 0 transition in Xenon ions

Collinear fast beam-laser spectroscopy has been performed on metastable 5d ⁴ D _7/2 Xenon ions. Hyperfine structure constants for the 6p ⁴ P _5/2 ⁰ level have been derived for¹²⁹Xe:A=?1,634.9±0.9 MHz and¹³¹Xe:A=485.3±0.3 MHz andB=?116.5±2.0MHz. Changes in mean squared nuclear charge radii are derived from the measured isotope shifts.     

Study of the mechanism of the 3He + p → p + p + d reaction at a 3He momentum of 5 GeV/c

The mechanism of the reaction ³He + p → p + p + d is studied by making use of the ITEP 80 cm liquid-hydrogen bubble chamber exposed to a beam of 5 GeV/c ³He nuclei. The reaction cross section is equal to 20.6 ± 0.3 mb. The phase-space regions associated with quasifree scattering (QFS) and final-state interactions (FSI) are selected. Angular, mass and momentum distributions of the reaction products are obtained in the entire kinematically allowed range. The experimental data in the QFS region are compared with theoretical calculations based on the simplest pole-diagram approximation. The ³He and deuteron wave functions (WF) correspond to the realistic RSC potential. The D-wave components of these WF are taken into account. The absolute value of the cross section and shape of the distributions are described as a whole reasonably well within the frame of the model considered in the kinematical region where FSI may be neglected. But at large spectator momenta there is an essential disagreement. The possible reasons for this are discussed.     

Vibrational and rotational excitation effects of the N(2D) + D2(X1Σg +) → ND(X3Σ+) + D(2S) reaction

The effects of the rovibrational excitation of reactants in the N(²D) + D₂(X¹Σ_g⁺) → ND(X³Σ⁺) + D(²S) reaction are calculated in a collision energy range from the threshold to 1.0 eV using the time-dependent wave packet approach and a second-order split operator. The reaction probability, integral cross-section, differential cross-section and rate constant of the title reaction are calculated. The integral cross-section and rate constant of the initial states v = 0, j = 0, 1, are in good agreement with experimental data available in the literature. The rotational excitation of the D₂ molecule has little effect on reaction probability, integral cross-section and the rate constant, but it increased the sideways and forward scattering signals. The vibrational excitation of the D₂ molecule reduced the threshold and broke up the forward–backward symmetry of the differential cross-section; it also increased the forward scattering signals. This may be because the vibrational excitation of the D₂ molecule reduced the lifetime of the intermediate complex.     

Isotopic Effects on Stereodynamics of the C~+ + H_2→CH~+ + H Reaction

The effects of isotope substitution on stereodynamic properties for the reactions C~+ + H_2/HD/HT →CH~+ + H/D/T have been studied applying a quasi classical trajectory method occurring on the new ground state CH_2~+ potential energy surface [J. Chem. Phys. 142(2015) 124302]. In the center of mass coordinates applying the quasi classical trajectory method to investigate the orientation and the alignment of the product molecule. Differential cross section and three angle distribution functions P(θ_r), P(ф_r), P(θ_r, ф_r) on the potential energy surface that fixed the collision energy with a value is 40 kcal/mol have been studied. The isotope effect becomes more and more important with the reagent molecules H_2 changing into HD and HT. P(θ_r, ф_r) as the joint probability density function of both polar angles θ_r and ф_r, which can illustrate more detailed dynamics information. The isotope effect is obvious influence on the properties of stereodynamics in the reactions of C~+ + H_2/HD/HT → CH~+ + H/D/T.     

Kinetics and dynamics of the S(1D2) + H2 → SH + H reaction at very low temperatures and collision energies

We report combined studies on the prototypical S(1D2) + H2 insertion reaction. Kinetics and crossed-beam experiments are performed in experimental conditions approaching the cold energy regime, yielding absolute rate coefficients down to 5.8 K and relative integral cross sections to collision energies as low as 0.68 meV. They are supported by quantum calculations on a potential energy surface treating long-range interactions accurately. All results are consistent and the excitation function behavior is explained in terms of the cumulative contribution of various partial waves.