激光触发SF6-N2混合气体开关的数值模拟

 在气体放电物理的基础上，对SF₆和N₂采用双光子电离模型，对碳氢化合物的光电离采用3能级模型，并考虑了混合气体的热电离和激光对气体的欧姆加热作用，建立了激光触发SF₆-N₂混合气体开关的数值模型，模拟了激光触发SF6-N2混合气体多级间隙开关实验。激光触发延迟时间的计算值与实验结果符合较好。理论计算表明：激光触发SF₆-N₂混合气体间隙开关的延迟时间随SF₆含量的增加呈上升趋势，而随激光脉冲能量、充气压力等的上升呈下降趋势。     

CO2在Pd表面吸附的热力学

 用密度泛函方法和相对论有效原子实势,分别对PdCO₂,PdCO和PdH的基态几何构型进行优化, 得到PdCO₂分子基态为Cs构型, Pd与CO2分子在同一平面, 键长PdC为0.203 0 nm, CO为0.118 3 nm, CO′为0.121 0 nm, 键角∠OCO′为154.215°,电子状态为1A′; PdCO分子基态电子状态为1+, 键长PdC为0.183 4 nm, CO为0.114 0 nm, 键角∠PdCO为180°; PdH分子基态为2∑, 键长PdH为0.152 6 nm。根据电子-振动近似理论计算了不同温度下金属Pd 与CO₂,CO及H2分子反应的生成热力学函数, 导出了反应平衡压力随温度的变化关系。分析认为杂质CO₂气体引起Pd合金膜中毒可能是由于CO₂分子吸附在Pd膜表面,形成Pd的CO₂化合物后,再自发分解为PdO和CO,而使Pd表面出现O和CO中毒所致。     

B12N12纳米笼：潜在的二氧化氮检测传感器

利用密度泛函理论通过计算吸附能量、HOMO/LUMO能隙变化、电荷转移、结构扭曲等研究二氧化氮分子在B12N12纳米笼的吸附．此外,通过计算B₁₂N₁₂的电子结合能、Gibbs自由能、态密度和分子表面的静电势研究其稳定性和其它特性．B₁₂N₁₂纳米笼吸附二氧化氮显示三种构型．B₁₂N₁₂团簇的HOMO/LUMO能隙变化对二氧化氮分子的存在非常敏感,从自由团簇的6.84 eV降为NO₂/团簇稳定团簇的3.23 eV．团簇的导电性被极大地提高,表明B₁₂N₁₂纳米簇可能是潜在的二氧化氮气体分子检测传感器.     

A-Z-A型石墨烯场效应晶体管吸附 效应的第一性原理研究

利用第一性原理的计算方法, 研究了A-Z-A型GNR-FET的电子结构和输运性质及其分子吸附效应. 得到了以下结论: 纯净的A-Z-A型GNR-FET具有典型的双极型晶体管特性, 吸附分子的存在会使纳米带能隙变小. 对于吸附H, H₂, H₂O, N₂, NO, NO₂, O₂, CO₂和SO₂分子的情况, A-Z-A型GNR-FET仍然保持着场效应晶体管的基本特征, 但吸附不同类型的分子会使GNR-FET的输运特性发生不同程度的改变; 对于吸附OH分子的情况, 输运特性发生了本质的改变, 完全不具有场效应晶体管的特性. 这些研究结果将有助于石墨烯气体探测器的工程实现, 并对应用于不同环境中GNR-FET的设计具有重要指导意义.     

密度泛函理论方法研究6H-SiC(0001)表面对氧分子和水分子的吸附

本文通过密度泛函方法计算6H-SiC(0001)表面对氧分子和水分子的吸附. 在6H-SiC(0001)表面上吸附的O₂分子自发地解离成O^*,并被吸收在C与Si原子之间的空位上. 吸附的H₂O自发地分解成OH^*和H^*,它们都被吸附在Si原子的顶部,OH^*进一步可逆地转化为O^*和H^*. H^*可以使Si悬键饱和并改变O^*的吸附类型,并进一步稳定6H-SiC(0001)表面并防止其转变为SiO₂.     

特定位点上CO2与(TiO2)n团簇相互作用的第一性原理研究

本文基于密度泛函理论系统地研究了(TiO₂)_n团簇上二氧化碳(CO₂)的吸附和活化性质. 计算结果表明,CO₂更倾向于吸附在(TiO₂)_n团簇的桥氧原子上,形成“化学吸附”碳酸盐络合物. 而CO更倾向于吸附到末端Ti-O的Ti原子上. 发现计算得到的碳酸盐振动频率值与实验获得的结果非常吻合,这表明配合物中CO₂的几何构型与其线性型相比,有微小的弯转. 通过对电子结构、电荷密度、电离势、HOMO-LUMO以及态密度的分析,证实了CO₂与团簇之间的电荷转移以及相互作用. 从预测的能量分布图来看,(TiO₂)_n团簇上的CO₂活化与结构密切有关,相比于块体的TiO₂,CO₂在团簇结构上更易于吸附和活化.     

NH3在Ni/Pt(111)和Ni/WC(001)表面上分解的第一性原理研究

采用密度泛函理论和slab模型,研究NH₃在Ni单原子层覆盖的Pt（111）和WC（001）表面上的物理与化学行为,计算了Ni单原子覆盖表面的电子结构以及NH₃的吸附与分解.表面覆盖的单原子层中,Ni原子的性质与Ni（111）面上的Ni原子明显不同.与Ni（111）相比,Ni/Pt（111）和Ni/WC（001）表面上Ni原子dz²轨道上的电子更多地转移到了其它位置,该轨道上电荷密度降低有利于NH₃吸附.在Ni/Pt（111）和Ni/WC（001）面上NH₃吸附能均大于Ni（111）,NH₃分子第一个N-H键断裂的活化能则明显比Ni（111）面上低,有利于NH₃的分解,吸附能增大使NH₃在Ni/Pt（111）和Ni/WC（001）面上更倾向于分解,而不是脱附.N₂分子的生成是NH₃分解的速控步骤,该反应能垒较高,说明N₂分子只有在较高温度下才能生成.WC与Pt性质相似,但Ni/Pt（111）和Ni/WC（001）的电子结构还是有差异的,与Ni（111）表面相比,NH₃在Ni/Pt（111）表面上分解速控步骤的能垒降低,而在Ni/WC（001）上却升高.要获得活性好且便宜的催化剂,需要对Ni/WC（001）表面做进一步改进,降低N₂分子生成步骤的活化能.     

钇覆盖Si@Al12团簇的贮氢性能

利用密度泛函理论系统地研究了Y_mSi@Al₁₂ (m=1—3)团簇及其贮氢性质. 结果表明, 在所研究的尺度范围内, 钇原子未在Si@Al₁₂团簇上团聚; 每个钇原子按18电子规则吸附氢分子, 其中Y₃Si@Al₁₂团簇可以吸附16个完整氢分子, 贮氢质量分数为5.0 %, 平均吸附能处于0.324—0.527 eV之间, 较为理想的吸附能说明在室温条件下吸氢和脱氢是可行的.     

环式M(SO2)(M=Zn, Cd)分子及其阴离子的基质隔离红外光谱和密度泛函理论计算

激光溅射锌和镉原子与SO₂分子反应的低温基质隔离红外光谱实验表明,在氩和氖的惰性基质中,形成了环式M(SO₂)分子及其阴离子M(SO₂)^- (M=Zn, Cd)．相关同位素(³⁴SO₂和S¹⁸O₂)替代实验及密度泛函理论计算均证实了这一结果．此外,自然电荷布居分析表明电子从金属锌和镉的s轨道转移到了SO₂配体上形成了M⁺(SO₂)^-“离子对”复合物,且该分子中的Zn-O键以及Cd-O键均表现出强的极化共价性．而Hg原子在与SO₂反应中所表现出来的惰性可由其较强的相对论效应所致的6s价电子层收缩与高电离电位得以解     

紧凑的非链式脉冲HF激光器

研究了气体组分和峰化电容对紫外光预电离脉冲HF激光器性能的影响.实验发现最佳气体混合比为SF₆/C₂H₆=20:1,峰化电容和主放电电容的最佳比为C_p/C_s=0.3,在最佳气体混合比时,最大激光脉冲峰值功率和对应的总气压随充电电压的提高而增大.同时得到了E/P值和激光能量的关系.整个器件的最大激光输出为400mJ,脉冲峰值功率为1.5MW,最大电光转换效率约为2.2%.     

Adsorption behaviour of SF6 decomposed species onto Pd4-decorated single-walled CNT: a DFT study

Metal nanocluster decorated single-walled carbon nanotubes (SWCNT) with improved adsorption behaviour towards gaseous molecules compared with intrinsic ones, have been widely accepted as a workable media for gas interaction due to their strong catalysis. In this work, Pd₄ cluster is determined as a catalytic centre to theoretically study the adsorption property of Pd₄-decorated SWCNT upon SF₆ decomposed species. Results indicate that Pd₄-SWCNT possessing good responses and sensitivities towards three composed species of SF₆ could realise selective detection for them according to the different conductivity changes resulting from the varying adsorption ability. The response of Pd₄-SWCNT upon three molecules in order is SOF₂ > H₂S > SO₂, and the conductivity of the proposed material is about to increase in SOF₂ and H₂S systems, while declining in SO₂ system. Such conclusions would be helpful for experimentalists to explore novel SWCNT-based sensors in evaluating the operating state of SF₆ insulation devices.     

Adsorption behaviour of SO2 and SOF2 gas on Rh-doped BNNT: a DFT study

Abstract

As the insulating medium, SF₆ is widely used in gas insulation equipment. Partial discharge and local overheating can cause the decomposition of SF₆, resulting in a decrease in insulation strength of the equipment. The detection of SF₆ decomposition gas can be used for on-line insulation detection of gas insulation equipment in electric power industry. In order to develop a new sensor gas sensing material for gas detecting. In this work, based on the first-principles density functional calculation (DFT) method of DMol³, the adsorption of SF₆ decomposition gas on (5,0) Z-type Rh-BNNT in different ways was explored. The adsorption energy, adsorption distance, charge transfer as well as density of states were discussed. The results show that the adsorption strength between SO₂ molecule with Rh-BNNT is larger than with SOF₂ molecule, combined with desorption time, theoretically predicts Rh -BNNT have the potential to be a material for SO₂ gas sensors.     

First-principle study on the structural and electronic properties of H2S and SO2 adsorption on Pd-doped MoS2 monolayer

The partial discharge in SF₆-insulated equipment produces characteristic decomposition products: SO₂ and H₂S. The characteristic decomposition products vastly speed up the process of discharge faults. Based on density functional theory (DFT) calculation, single layer Pd-doped MoS₂ (Pd-MoS₂) is adopted as the adsorbent to adsorb SO₂ and H₂S to ensure the operational stability of SF₆-insulated equipment. The adsorption energy, charge transfer and structure parameters of SF₆, H₂S, and SO₂ adsorption on the Pd-MoS₂ monolayer are analysed to find the most stable adsorption structure. The molecular orbital theory, total density of states and partial density of states are studied to analyse the adsorption mechanism. The results show that Pd-MoS₂ adsorbent possesses high catalytic activity and excellent adsorption performance to H₂S and SO₂ by strong chemical adsorption. This study is of great significance to ensure the operational stability of SF6-insulated equipment by removing these characteristic decomposition products.     

Electronic transport calculation of adsorbate NO<Subscript>2</Subscript> and NO molecules on graphene using Maximally Localized Wannier functions

In this paper we have investigated the adsorption of the gas molecules (NO₂, NO) on graphene, using first-principles methods. For full geometric relaxation of the molecules in the vicinity of a graphene sheet, we obtain the adsorption geometry, adsorption energies, charge transfer and density of states (DOS). We can identify which of the adsorbate molecules is acting as donor or acceptor. We find that the conductance of graphene at the Fermi level decreases with adsorbing NO₂ molecules and increases with adsorbing NO molecules.     

The Application of SF6 in the Geochemical Research

For mass spectrometric measurements of δ³¹S, pure sulphur hexafluoride was prepared quantitatively from different mineral sulphides by the reaction with elemental fluorine under pressure. The results of δ³¹S measurements on SF₆ samples were confirmed by comparison of δ³¹S values with the classical method leading to SO₂. Numerous mass spectrometric measurements of SF₆ and SO₂ with regard to the experimental conditions of the synthesis, the influence of background, memory effect, and adsorption were made. The measurements of small isotopic variations of sulphur with SF₆ has advantages in comparison to the SO₂ technique. The method described can be successfully used for routine work.     

Total cross sections of electron scattering by several sulfur-containing molecules OCS, SO2, SF4, SF6, SF5CF3, SO2Cl2 and SO2ClF at 30–5000?eV

Total cross sections of electron scattering by several sulfur-containing molecules OCS, SO₂, SF₄, SF₆, SF₅CF₃, SO₂Cl₂ and SO₂ClF are calculated at the Hartree-Fork level employing the modified additivity rule approach. The modified additivity rule approach, which was proposed by Shi et al. [Eur. Phys. J. D 45, 253 (2007); Nucl. Instrum. Meth. B 254, 205 (2007)], takes into consideration that the contributions of the geometric shielding effect vary as the energy of incident electrons, the target’s molecular dimension and the atomic and electronic numbers in the molecule. The present investigations cover the impact energies ranging from 30 to 5000 eV. The quantitative total cross sections are compared with those obtained by experiments and other theories. Good agreement is observed even at energies of several tens of eV. It shows that the modified additivity rule approach is applicable to carry out the total cross section calculations of electron scattering by these sulfur-containing molecules at intermediate and high energies, especially over the energy range above 100 eV or so. In the present calculations, the atoms are still represented by the spherical complex optical potential, which is composed of static, exchange, polarization and absorption terms.     

Infrared synthesis of SO3 by homogeneous gas-phase CO2 laser-driven reactions

By using a CO₂ laser operated at 10.6μm, a bimolecular reaction was induced in a binary SO₂/O₂ gas mixture, with a sensitizer gas (SF₆) as photo-absorbing species.The infrared (IR) synthesis of SO₃ was performed in a flowing gas device equipped with a continuous trapping system of the reaction product. Vibrational energy transfer processes presumably should play a specific role in SO₂ excitation and reaction in the presence of SF₆.     

Selective multiphoton IR dissociation of SF6 molecules under nonequilibrium conditions of a pulsed gasodynamically cooled molecular flow interacting with a solid surface

The process of the isotope-selective multiphoton IR dissociation of SF₆ molecules under the non-equilibrium conditions of a pulsed gasodynamically cooled molecular flow interacting with a solid surface was experimentally studied. The SF₆ molecules dissociate as a result of excitation in a shock wave generated in the flow, in the flow incident onto the sold surface, and in an unperturbed flow (in the absence of the solid). The experiment was based on detecting the luminescence from HF^* molecules (λ ≈ 2.5) μm) accompanying the SF₆ dissociation in the presence of H₂ or CH₄, the emission intensity being a measure of the SF₆ dissociation yield. The molecular beam parameters were studied. The time-of-flight spectra of SF₆ in the flow interacting with the surface were measured under various experimental conditions. The spectral and energy characteristics of the SF₆ dissociation process were determined in the flow interacting with the solid surface and in the unperturbed flow. The dissociation product (SF₄) yield was measured and the coefficient of its enrichment with the ³⁴S isotope was determined. It is demonstrated that, using the shock wave formation, it is possible to increase the efficiency of the isotope-selective dissociation of SF₆ molecules. An explanation of the observed results is proposed. The gas density and temperature in the incident flow and in the shock wave were estimated. The results are analyzed and compared to the other published data on the SF₆ dissociation in a molecular beam.     

Experimental investigations of the formation of XeF*(B 2II1/2) excimer molecules during the injection of SF6 into a xenon plasma flow

The luminescence of XeF*(B ²II_1/2) molecules from a zone formed in the injection of SF₆ gas into a freely flowing xenon plasma jet is investigated. The experiments show that both the energy characteristics of the luminescence and the geometrical dimensions of the plasmachemical reaction zone can be controlled by varying the power input to the plasmatron and the mass flow rates of SF₆ and the xenon plasma. It is shown that the main contribution to the production of XeF*(B ²II_1/2) excimer molecules under the given experimental conditions is from two-particle ion-ion reactions involving Xe ions and SF ₆ ⁻ and SF ₅ ⁻ molecular ions. Zh. Tekh. Fiz. 68, 36–42 (February 1998)     

The formation of an intense secondary pulsed molecular beam and obtaining accelerated molecules and radicals in it

A method for obtaining an intense secondary pulsed molecular beam is described. The kinetic energy of molecules in the beam can be controlled by vibrational excitation of the molecules in the source under high-power IR laser radiation. A compression shock (shock wave) is used as a source of secondary beams. The shock wave is formed in interaction between an intense pulsed supersonic molecular beam (or flow) and a solid surface. The characteristics of the secondary beam were studied. Its intensity and the degree of gas cooling in it were comparable with the corresponding characteristics of the unperturbed primary beam. Vibrational excitation of molecules in the shock wave and subsequent vibrational-translational relaxation, which occurs when a gas is expanded in a vacuum, allow the kinetic energy of molecules in the secondary beam to be substantially increased. Intense [≥10²⁰ molecules/(sr s)] beams of SF₆ and CF₃I molecules with kinetic energies approximately equal to 1.5 and 1.2 eV, respectively, were generated in the absence of carrier gases, and SF₆ molecular beams with kinetic energies approximately equal to 2.5 and 2.7 eV with He (SF₆/He=1/10) and H₂ (SF₆/H₂=1/10) as carrier gases, respectively, were obtained. The spectral and energy characteristics of acceleration of SF₆ molecules in the secondary beams were studied. The optimal conditions were found for obtaining high-energy molecules. The possibility of accelerating radicals in secondary molecular beams was demonstrated.