Introduction
The system of S+H2 has been studied in both theoretical1-9 and experimental1011 methods due to its important role in combustion and atmospheric chemistry. Maiti et al.4 have studied the intersystem crossing effect in the reaction S+H2 by employing a “mixed” representation approach in conjunction with a trajectory surface-hopping method. They have compared the intersystem crossing effect with that of the reaction O+H2. Klos et al.6 have reported their theoretical study on the S(1D)+H2/D2→SH+H/SD+D reaction, including the nonadiabatic effect. They found that the dependence of the cross-sections upon the product rotational quantum number shows a statistical behavior, which is similar to the result computed with the simple prior statistical model. In the study of Berteloite et al.,7 kinetics and crossed-beam experiments were performed in experimental conditions approaching the cold energy regime. By employing the quantum mechanical (QM) hyperspherical reactive scattering method and quasi-classical trajectory (QCT) and statistical quasi-classical trajectory (SQCT) approaches, Lara et al.8 have calculated the reaction probabilities as a function of total angular momentum (opacity function) and the resulting reaction cross-section for the reaction S+H2 at low energies (0.09-10 meV) based on two different ab initio potential energy surfaces (PESs). S. H. Lee and Liu1011 have investigated the S(1D)+H2, D2, and HD reactions through Dopplerselected time-of-flight detection of the H or D product. They have determined the excitation functions and the differential cross-section at several collision energies, as well as the isotopic branching in the S(1D)+HD reaction.
The inverse reaction H+HS has also attracted the attentions. The first global potential energy surface was reported by Martin12 in 1983 and the reaction H+HS calculation is performed. In 2012, an accurate ab initio potential energy surface (PES) for the lowest triplet state of H2S was reported by Lv et al..13 The exact quantum dynamical studies on both the abstraction and exchange channels by using this PES have been presented. The results show that there is no well on the H+HS→H2+S reaction channel (abstraction channel) and the minimum energy paths (MEP) of the abstraction process occur at the collinear configuration. This indicates that the height of the barrier for the abstraction process will increase when the H-H-S bond angles decrease from 180˚ to 0˚. In Ref. 13, the barrier of the reaction H+HS→H2+S is about 0.09 eV.
The stereo-dynamic studies, providing direct insight into the underlying chemical process based on vector properties, have been performed recently.14-23 The vector properties such as orientation and alignment of the product molecules for the reaction A+BC→AB+C were investigated in detail, especially by Han et al..18-2123 Combined with scalar ones, the vector properties can help to reveal the details of the reaction with rich space information. As mentioned above, most of the investigations on the reaction S+H2 and its inverse reaction H+HS basically deal with the scalar properties. To our best knowledge, only one study has been reported thus far concerning the stereo-dynamics of the reaction H+HS. Bai et al.24 performed the QCT calculations on both the H+HS→H2+S and H+SH'→HS+H' reactions. The scalar properties including the reaction probability and integral cross section are calculated in their work, the vector correlations such as k-k', k-j' and k-k'-j' are presented as well.
In this work, we have the further QCT calculations employing the newest potential energy surface (PES) constructed by Lv et al..13 Though the collision energy effect on the stereo-dynamics of the title reaction has been studied by Bai et al.,24 we argue that the reaction is so significant in dynamical features that it merits further study. In this paper, the ro-vibrational distributions at lower collision energies have been obtained, which are entirely different from the vibrational distributions at higher collision energies. In addition, the opacity function is calculated and the four generalized polarization-dependent differential cross-section (PDDCSs) are discussed in details. This shows that our current study on the stereo-dynamics of the title reaction is of great significance. This work is organized as follows: Section 2 reviews the theoretical methodologies used in the present study. Section 3 presents the calculated results and discussion. The conclusion is presented in Section 4.
Quasi-classical Trajectory Method
The quasi-classical trajectory (QCT) method employed in this study is the same as the method has been used in previous works.16-1823 In our calculation, the classical Hamilton’s equations are numerically integrated for motion in three dimensions, and the accuracy of the calculation is verified by checking the conservation of both the total energy and angular momentum. The forms of the Hamilton’s equations in the QCT method are:
Where rAB, rBC and rAc means the internuclear distance of AB, BC and AC. mA, mB and mC indicate the mass of atom A, B and C. μBC present the reduced mass of atom A and B, μA-BC present the reduced mass of atom A and molecule BC.
In addition, the zero-point energy (ZPE) leakage and tunneling play important roles in some reactions, and they are the most severe shortcomings of QCT simulations. However, when it comes to the reaction H+HS, the quantum effects have little influence on the calculation of the reaction probability.13 A batch of 100000 trajectories were run for each energy for the title reactions and the integration step size in the trajectories was chosen to be 0.1fs, which guarantees the conservation of the total energy and total angular momentum. The maximum value of the impact parameter, bmax, was computed by calculating 100000 trajectories at fixed values of the impact parameter, b, systematically increasing the value of b until no reactive trajectories were obtained. The reaction probability, Pr = Nr/Nt, is the ratio of the number of reactive trajectories to the total number of trajectories, while the integrate cross section (ICS) is calculated by , N(b) and NR(b) being the numbers of total and reactive trajectories in a subdivided interval Δb between 0 and bmax, respectively. The rate constants can be calculated once the ICSs as a function of collision energy are obtained. Using the statespecific ICSs σvj for each initial ro-vibrational state of HS and by assuming a Maxwell-Boltzmann distribution over collision energy (Ec), we obtain the specific rate constant kvj at a temperature T given by the standard equation:
Figure 1.The center-of-mass coordinate system used to describe the k, k and j' correlation.
The rate constants can be calculated once the ICSs as a function of collision energy are obtained. Using the statespecific ICSs σvj for each initial ro-vibrational state of HS and by assuming a Maxwell-Boltzmann distribution over collision energy (Ec), we obtain the specific rate constant kvj at a temperature T given by the standard equation:
Where σvj(Ec), is the ICS at Ec (collision energy), μ is the HS-H reduced mass and kB is the Boltzmann constant.
The center-of-mass (CM) frame151721 is chosen to describe the vector correlation, and its details are specified as follows. As can be seen in Figure 1, k is the reactant relative velocity parallel to the z-axis, and k represents the product relative velocity. The x-z plane, containing vectors k and k, is the scattering plane. θt depicts the angle between k and k, which indicates the scattering direction of the product. j is the rotational angular momentum of product, whose polar and azimuthal angles are θr and φr, respectively. P(θr) and P(φr) describe the probability density distribution of reaction products, reflecting k-j and k-k-j vector-correlation respectively. The alignment and orientation of j can be obtained by analyzing P(θr) and P(φr) distributions. Four generalized polarization-dependent differential cross-sections (PDDCSs) are used to describe the full three-dimensional angular distribution associated with k-k-j correlation in the CM frame. The fully correlated center-of-mass angular distribution is written as1518:
Where [k] = 2k + 1, (1/σ)(dσkq/dωt) is the generalized polarization-dependent differential cross section (PDDCS) and ckq(θr, φr) are the modified spherical harmonics. The PDDCS is written in the following form:
where the is evaluated by the expected value expression,
where the angular brackets represent an average over all angles.
The differential cross section is given by
The function f(θr) can be expanded in a set of Legendre polynomials1518
Thus, l = 2 indicates the product rotational alignment.
Where, P2 is a second Legendre moment, and the brackets show an average over the distribution of j' about k.
The P(θr) distribution can be expanded in a serious of Legendre polynomials1518 as:
The expanding coefficient are called orientation (k is odd) and alignment (k is even) parameter.
The dihedral angle distribution P(φr) can be expanded in Fourier series1620
Results and Discussion
Before making further discussion on our calculated results, we compared our QCT reaction probability and ICS for both the abstract reaction and exchange reaction with the QM results.13 As shown in Figure 2, our QCT results are in good agreement with that the QM result from ref.13. This because the quantum effect is not significant in both the abstract and exchange reactions. What’s more, the good agreement between QCT and QM results indicates the accuracy of our calculations and the reliability of our discussion.
To obtain a elementary study on the title reaction, we have calculated the reaction probability as a function of the impact parameter b, which is named the opacity function P(b). Figure 3 depicts the QCT opacity function for the reaction H+HS(v = 0, j = 0)→H2+S at four different collision energies. Clearly, the maximum impact parameter bmax doesn’t change as the collision energy increases. For b less than 1.2 Å, Pr decreases with the increase of the collision energy. At the collision energies of 0.8 and 1.2 eV, the reaction probability tends to decrease as b increases. While, at 1.6 and 2.0 eV, a bell shape is found with peaks located at about b = 1.2 Å. It can be concluded that the reactivity with small impact parameter is blocked at high collision energy. This may result from the repulsive potential energy surface (PES). As the collision energy increases, more repulsive regions of the potential energy surface become available and the reactions with small impact parameter are restrained. In addition, the reaction mechanism of the title reaction should be taken in to account.
Figure 2.(a) the QCT and QM reaction probabilities for the reactions H+HS and H+SH. (b) the QCT and QM ICSs for the reactions H+HS and H+SH.
Figure 3.Reaction probability as a function of the impact parameter b at 0.8, 1.2, 1.6 and 2.0 eV for H+HS(v = 0, j = 0)→H2+S.
Figure 4.(a) QCT cross section as a function of the collision energy for the reaction H+HS(v = 0, j = 0, 1)→H2+S (b) QCT rotational state-specific thermal rate constant k(T) for the reaction H+HS(v = 0, j = 0, 1)→H2+S in the temperature range 500-6000 K.
The QCT ICSs were calculated for different rotational states of reactant HS (v = 0, j = 0, 1). Figure 4(a) presents the excitation functions, i.e., ICS as a function of collision energy, for the rotational states j = 0 and j = 1 of HS. It can be seen clearly, the reaction threshold is 0.09 eV. This result illustrates that the barrier height of the abstraction reaction H+HS→H2+S is 0.09 eV. The conclusion is accord with that in Ref.13. In Figure 4(a), the curves of the excitation function have the same shape for the different reagent rotation of HS. As the collision energy increases, the integral cross sections reach a high value at 0.8 eV rapidly and then drop slightly after a plateau between 0.8 and 1.2 eV. This tendency is similar with the previous studies for other abstraction reactions H+HBr25 and H+HCl.26 The decrease of ICS for the title reaction results from the fact that the total reaction probability decreases as the collision energy increases. In addition, Figure 4(a) shows that the influence of rotational excitation on HS on ICS is extremely small. Indeed, ICSs change slightly as the rotational quantum number j of HS increases.
Based on the QCT excitation functions, Figure 4(b) shows the thermal rate constants for the rotational states j = 0, j = 1 of HS over a wide range of temperatures between 500K and 6000 K. We note that the two thermal rate constants have the same temperature dependence and that the k00 and k01 increase monotonously as the temperature increases in the range of 500-6000 K. We also found that the effect of the reagent rotational states can be negligible.
To get more insight into the effect of collision energy, the ro-vibrational (v', j') distributions of the product H2 are calculated in this work. Figure 5 shows the ICSs for the product vibrational distribution at collision energies range from 0.2 to 2.0 eV on the reaction H+HS(v = 0, j = 0)→ H2+S. We can find that the vibrational excitation of H2 enhance with the collision energy increasing. As we can see, at the low collision (0.2 and 0.4 eV), the ICSs peaks are found at v' = 1 and decrease when the vibrational exited increase. For the high collision energies (0.8, 1.2, 1.6 and 2.0 eV), the most populated vibrational level is v' = 0 and ICS regularly decreases with the increase of v'. It can be concluded that the reactions which produce H2 with high vibrational states are restrained. The vibrational stateresolved ICS at v' = 0 decreases distinctly with the increase of collision energy in the range of 1.2-2.0 eV. However, at v' = 2, 3 and 4, it shares a slight increment with the collision energy. These reflect the decrease of the total ICS as collision energy increases.
Figure 5.Product vibrational distributions for the reaction H+HS (v = 0, j = 0)→H2+S at 0.2, 0.4, 0.8, 1.2, 1.6 and 2.0 eV.
Figure 6 shows the ICSs for ro-vibrational distribution (v' = 0-8, j' = 0-9) of the product H2 at collision energies range from 0.2 to 2.0 eV on the reaction H+HS(v = 0, j = 0) →H2+S. It is obvious that the rotational excitation of H2 enhances as the collision energy increases. In Figure 6, when the collision energy increases, the peaks of the rotational excitation shift to the lager rotational quantum number j'. This means that the high rotational excitations become gradually more populated when the collision energy increases. At a given collision energy, the shape of the rotational distributions appears to be distinct for different vibrational levels. The peak of the rotational distributions moves to the smaller j' with increase of v'. At v' = 0, for each collision energy, the ICS increases sharply with j', reaches a maximum at a high j' and decreases to negligible values before reaching the last states accessible. However, at the vibrational excited states, bell-shaped curves are visible.
Figure 6.The product rotational distributions on different product vibrational states. Integral cross section at 0.2, 0.4, 0.8, 1.2, 1.6 and 2.0 eV for the H+HS(v = 0, j = 0)→H2+S reaction.
The polarization dependent generalized cross-sections (PDDCSs) depict the k-k'-j' correlations. Four PDDCSs for the title reaction at collision energies of 0.2, 0.4, 0.8, 1.2, 1.6 and 2.0 eV are shown in Figure 7. The PDDCS (2π/σ)(dσ00/dωt) only describes the scattering directions of the product or the k-k' correlation. The (2π/σ)(dσ00/dωt) for the reaction H+HS(v = 0, j = 0)→H2+S is shown in Figure 6(a). It can be clearly seen that the scattering directions of H2 are closely related to the collision energy. At lower collision energies of 0.2 and 0.4 eV, the scattering direction of the product H2 is strongly backward and sideways. As the collision energy increases, the forward scattering strengthen remarkably. The influence of the collision energy on the (2π/σ)(dσ00/dωt) may be attributed to the impulsive effect. With the increase of the collision energy, more repulsive regions of the potential energy surface become available. However, the growth of collision energies con not supplement the more repulsive parts of the surface energetically accessible, which causes an obvious tendency of the forward scattering with the increase of collision energy. The (2π/σ)(dσ20/dωt) is related to the alignment parameter P2( j'·k), which shows an opposite distribution trend with that of the (2π/σ)(dσ00/dωt) and indicates the alignment of the product angular momentum j' perpendicular to k. It can be easily seen, in Figure 6(b) that the j' is preferentially polarized along the direction perpendicular to k. The negative value of the peak of (2π/σ)((dσ20/dωt) becomes smaller with the increment of collision energy in the range of 0.2-0.8 eV, which indicates that the alignment of j' becomes weaker. When the collision energy increases from 0.8 to 2.0 eV, the alignment of j' becomes stronger with the negative value of the (2π/σ)(dσ20/dωt) being larger.
Figure 7.Four PDDCSs for the reaction H+HS(v = 0, j = 0)→H2+S at six collision energies.
At θt= 0 and θt = 180°, the PDDCSs (2π/σ)(dσ22+/dωt) and (2π/σ)(dσ21−/dωt) are both nearly zero.17 Figure 7(c) shows that the values of (2π/σ)(dσ22+/dωt) are almost negative for all scattering angles at the lower collision energies of 0.2 and 0.4 eV, which indicates the notable preference of the alignment along the y-axis. Clearly, the negative value of (2π/σ)(dσ22+/dωt) at 0.4 eV is much smaller than that at 0.2eV, reflecting a weaker alignment of j'. At the higher collision energies of 0.8, 1.2, 1.6 and 2.0 eV, the values of (2π/σ)(dσ22+/dωt) are negative at smaller scattering angles (0° < θ < 70°) and are positive at larger scattering angles (70° < θ <180°). As collision energy increases, both the negative values of (2π/σ)(dσ22+/dωt) increase, indicating that the alignment of j' is stronger. However, the positive values of (2π/σ)(dσ22+/dωt) also increase, which may affect the alignment of j'. We can conclude that the degree of the alignment of is firstly strongly weakened and then enhanced when the collision energy increases. The (2π/σ)(dσ21−/dωt) is related to the orientation of product rotational angular momentum, which will be discussed later.
Figure 8 shows the P(θr) distributions for the reaction H+HS at six collision energies. In all cases, the symmetric P(θr) distributions exhibit a maximum at θr = 90°, which shows that the product rotational angular momentum vector j' is strongly aligned along the direction perpendicular to the k vector. It is also clear in Fig. 8 that the distribution of P(θr) becomes much weaker when the collision energy increases from 0.2 eV to 0.4 eV, while it becomes stronger when the collision energy increases from 0.4 eV to 1.2 eV. When the collision energy increases from 1.2 eV to 1.6 eV, the alignment of j' becomes weaker again, and it hardly changes when the collision energy is larger than 1.6 eV.
Figure 8.The distribution of P(θr) for the reaction H+HS(v = 0, j = 0)→H2+S, reflecting k-j' correlation at six collision energies 0.2, 0.4, 0.8, 1.2, 1.6 and 2.0 eV.
The alignment parameters 〈P2( j′ · k)〉 are plotted in Figure 9, which give a simple way to express the degree of the product rotational alignment effect. It can be seen from Figure 9 that the 〈P2( j′ · k)〉 values increase evidently when the collision energy is below 0.4 eV and drops remarkably from 0.4 eV to 2.0 eV. This indicates that the product alignment becomes weaker and then stronger as collision energy increases. This result is distinctly different from that of P(θr). Although the 〈P2( j′ · k)〉 gives a simple way to express the product alignment, it is not enough to express the degree of the product rotational alignment for the title reaction.
Figure 9.The product rotational alignment parameter 〈P2( j′ · k)〉 for the reaction H+HS(v = 0, j = 0)→H2+S as a function of collision energies.
Figure 10 depicts the P(φr) distribution for the reaction H+HS(v = 0, j = 0)→H2+S at six collision energies 0.2, 0.4, 0.8, 1.2, 1.6 and 2.0 eV. For all the collision energies, the P(φr) distributions are asymmetric with respect to the scattering plane (or about φr = 180°), with a peak appearing at φr = 270°. This means an obvious preference for orientation along the negative y-axis, and implies a preference for the left-hand rotation of the product H2. As Figure 10 shows, the peak of P(φr) at 0.2 eV is high and narrow, reflecting the strong orientation of the product rotational angular momentum. It can be concluded that the in-plane mechanism dominate the title reaction at lower collision energies. When the collision energy increases in the range of 0.2-0.8 eV, the peak of P(φr) has a sharp decrease, indicating an evident weakness of the orientation. The P(φr) distribution changes slightly when the collision energy increases from 0.8 eV to 2.0 eV, which shows that the energy effect on the product orientation is almost negligible in the region of the higher collision energy.
Figure 10.The dihedral angle distribution of P(φr) for the reaction H+HS(v = 0, j = 0)→H2+S at six collision energies 0.2, 0.4, 0.8, 1.2, 1.6 and 2.0 eV.
Conclusion
To summarize our work, a series of QCT calculations have been performed to investigate the influence of collision energy on the stereo-dynamics. The newest potential energy surface reported by Lv et al. is employed in our calculations. It is found that the ICSs increase and then decrease as the collision energy increases. The effect of the initial rotational states on the ICSs and the thermal rate constants is negligible. Both the vibrational and rotational excitation of the products molecule H2 enhance when the collision energy increases. And the results indicate that the reactions which produce H2 with high vibrational states are restrained. The rotational distributions are sensitive to both the product vibrational excitation and collision energy. In addition, the vector correlations are computed and discussed. It is concluded that the scattering direction moves forward as the collision energy increases. For lower collision energies, the energy has a negative influence on both the alignment and orientation of the product angular momentum. However, the influence of collision energy is not obvious when the collision energy is higher.
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