1O～3O T恒定磁场下碱金属原子的边界轮廓

孤立原子是具有球对称性的.如果将孤立原子置于磁场中,原子的边界半径必然会发生变化.根据原子边界轮廓理论模型,研究和计算了在10～30 T磁场强度下碱金属原子的边界轮廓,可供有关参考.     

匀强电场中基态惰性原子的边界轮廓

应用原子特征边界轮廓模型, 计算了在5.292×10^-5 - 5.292×10^-3 a.u. 匀强电场下, 基态惰性原子的边界轮廓. 计算结果表明, 在电场中原子的边界轮廓呈现近椭球形, 轮廓的变化随电场强度的增强而增大; 在电场强度不变的情况下, 原子边界轮廓的变化随原子序数的增加而增大. 并且计算中得到的单位强度原子平均径向变化率与原子极化率实验结果呈现很好的线性相关性.     

Zeeman原子吸收光谱分析法中谱线轮廓的研究I.原子发射谱线.原子吸收谱线和Zeeman原子吸收谱线轮廓间重叠关系图的建立

详细报道用理论计算和绘制的37个元素分析线的发射轮廓. 吸收线轮廓和Zeeman分裂后的吸收线轮廓, 并建立了在原子吸收光谱法中三者轮廓间的重叠关系     

关于分子特征形状的理论

借助于分子中电子运动的经典转折点, 定义了分子的内禀特征轮廓. 文中以甲烷、甲醇和甲酸为例, 详细介绍了分子内禀特征轮廓理论方法. 对分子轮廓的特征截面的具体分析, 可以给出形成分子过程中原子的空间变化信息. 首次计算和绘出了上述分子轮廓上的电子密度分布图, 它与分子的化学性质密切相关, 给出了对分子边界的新认识.     

Zeeman原子吸收光谱分析法中谱线轮廓的研究 Ⅰ.原子发射谱线、原子吸收谱线和Zeeman原子吸收谱线轮廓间重叠关系图的建立

详细报道用理论计算和绘制的37个元素分析线的发射线轮廓、吸收线轮廓和Zeeman分裂后的吸收线轮廓,并建立了在原子吸收光谱法中三者轮廓间的重叠关系图.     

关于分子特征形状的理论--Ⅱ.几个典型有机分子的内禀特征轮廓

借助于分子中电子运动的经典转折点,定义了分子的内禀特征轮廓.文中以甲烷、甲醇和甲酸为例,详细介绍了分子内禀特征轮廓理论方法.对分子轮廓的特征截面的具体分析,可以给出形成分子过程中原子的空间变化信息.首次计算和绘出了上述分子轮廓上的电子密度分布图,它与分子的化学性质密切相关,给出了对分子边界的新认识.     

Zeeman原子吸收光谱分析法中谱线轮廓的研究I.原子发射谱线.原子吸收谱线和Zeeman原子吸收谱线轮廓间重叠关系图的建立

详细报道用理论计算和绘制的37个元素分析线的发射轮廓. 吸收线轮廓和Zeeman分裂后的吸收线轮廓, 并建立了在原子吸收光谱法中三者轮廓间的重叠关系     

利用探针分子红外光谱识别和表征铂族金属基单原子催化剂

单原子催化是提高贵金属利用率的有效手段,而表征单原子催化剂是理解单原子催化的基础.探针分子红外光谱可用于识别和定量催化剂样品中孤立的Pt族金属物种的浓度,从而得到负载的孤立的Pt族金属物种的局部几何形状、稳定性、活性及其分散性.本文讨论了该技术用于识别和表征含负载型孤立的Pt族金属原子催化剂的效能、应用、以及未来的发展方向.     

异原子配位结构碳基单原子电催化剂结构与性能相关性的研究进展

单原子催化剂是一类以相互孤立的单个金属原子作为催化活性中心的、 具有高原子经济性及高活性的负载型催化剂, 被广泛应用于能源电催化领域. 近年来, 通过使用两种或两种以上原子与活性中心金属原子配位, 构建具有异原子配位结构的单原子材料, 展现了优异的电催化性能. 研究发现, 这种不对称的配位结构有效调控了中心金属原子的电子结构, 优化了催化反应的吸附和脱附能量, 提高了电催化的性能. 本文综合评述了具有异原子配位结构碳基单原子电催化剂的合成策略、 表征技术与方法, 以及在前沿能源电催化应用中的催化剂性能与结构之间的构效关系, 并展望了异原子配位结构碳基单原子电催化剂的研究前景.     

原子的边界半径

本文建议和讨论2了原子大小的一种新量度-原子的边界半径, 经出了边界半径的周期表。对于惰性气体原子和汞原子, 有实验测得的有效半径, 它们与边界半径符合得相当好。原子的边界半径与实验的van der Waals半径有良好的线性关系。因此, 由边界半径可以预言某些原子的有效半径以及van der Waals半径。     

Generalized hybrid orbital for the treatment of boundary atoms in combined quantum mechanical and molecular mechanical calculations using the semiempirical parameterized model 3 method

The application of combined quantum mechanical (QM) and molecular mechanical methods to large molecular systems requires an adequate treatment of the boundary between the two approaches. In this article, we extend the generalized hybrid orbital (GHO) method to the semiempirical parameterized model 3 (PM3) Hamiltonian combined with the CHARMM force field. The GHO method makes use of four hybrid orbitals, one of which is included in the QM region in self-consistent field optimization and three are treated as auxiliary orbitals that do not participate in the QM optimization, but they provide an effective electric field for interactions. An important feature of the GHO method is that the semiempirical parameters for the boundary atom are transferable, and these parameters have been developed for a carbon boundary atom consistent with the PM3 model. The combined GHO-PM3/CHARMM model has been tested on molecular geometry and proton affinity for a series of organic compounds.Acknowledgement We thank the National Institutes of Health for support of this research.Contribution to the Jacopo Tomasi Honorary Issue     

Ionization of 1-D model atom in an intense laser field based on asymptotic boundary conditions and symplectic algorithm

In this paper the asymptotic boundary condition (ABC) of 1-D model atom in the intense laser field at the spatial sufficiently far distance is presented using Fourier transformation on the condition that the initial state is local and the atomic potential in the model falls off rapidly. On the basis of this ABC, the symplectic algorithm is developed for computing the model atom in the intense laser field. The ABC and symplectic algorithm are applied to compute the ionization behaviors for 1-D Pöschl–Teller short-range potential. The numerical results illustrate that the ABC and the symplectic algorithm presented are reasonable and effective for 1-D model atom in the intense laser field.     

A dipole interaction model for magnetochiral birefringence

We have developed a classical model to investigate the magnetochiral birefringence of an isotropic chiral medium submitted to a longitudinal magnetic field. This model, which is an extension of the atom dipole interaction model, yields direct calculations from the polarizabilities and positions of the atoms of the considered molecules. The numerical values obtained for the magnetochiral birefringence, as well as for the optical activity and Faraday rotation, are supported by the previously published experimental results on limonene, proline, and tartaric acid.     

A laser photolysis study of the effect of a magnetic field on the kinetics of the recombination of radical and radicalion pairs in micelles

Conclusions The recombination of the radical pairs formed upon the transfer of a hydrogen atom from phenols and amines to triplet quinones in micelles is hindered upon the application of an external magnetic field and accelerated in the presence of atmospheric oxygen. The magnetic field effect is explained within the framework of a relaxation mechanism. The magnetic field has no effect on the kinetics of the deactivation of triplet exciplexes in micelles.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 2, pp. 464–467, February, 1986.     

Inhomogeneous Electron Liquid in a Homogeneous Magnetic Field of Arbitrary Strength

Abstract

Our recent paper [Phys. Rev. A, 60, 2853 (1999)] on the field dependence of the energy of a molecule in an arbitrary magnetic field is extended here by results which can be expressed solely in terms of the total kinetic energy of the electron liquid of a molecule or an atom in a homogeneous magnetic field.     

Magnetically activated micromixers for separation membranes

Presented here is a radically novel approach to reduce concentration polarization and, potentially, also fouling by colloids present in aqueous feeds: magnetically responsive micromixing membranes. Hydrophilic polymer chains, poly(2-hydroxyethyl methacrylate) (PHEMA), were grafted via controlled surface-initiated atom transfer radical polymerization (SI-ATRP) on the surface of polyamide composite nanofiltration (NF) membranes and then end-capped with superparamagnetic iron oxide magnetite (Fe(3)O(4)) nanoparticles. The results of all functionalization steps, that is, bromide ATRP initiator immobilization, SI-ATRP, conversion of PHEMA end groups from bromide to amine, and carboxyl-functional Fe(3)O(4) nanoparticle immobilization via peptide coupling, have been confirmed by X-ray photoelectron spectroscopy (XPS) and field emission scanning electron microscopy (FESEM). These nanoparticles experience a magnetic force as well as a torque under an oscillating external magnetic field. It has been shown, using particle image velocimetry (PIV), that the resulting movement of the polymer brushes at certain magnetic field frequencies induces mixing directly above the membrane surface. Furthermore, it was demonstrated that with such membranes the NF performance could significantly be improved (increase of flux and salt rejection) by an oscillating magnetic field, which can be explained by a reduced concentration polarization in the boundary layer. However, the proof-of-concept presented here for the active alteration of macroscopic flow via surface-anchored micromixers based on polymer-nanoparticle conjugates has much broader implications.