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- The first term is the screened Coulomb repulsion. 第一项是屏蔽的库仑排斥项。
- Coulomb repulsion imposes the need for high temperature. 库仑斥力增添了对高温的需求。
- Why doesn't it fly apart under the coulomb repulsion of like-charge elements? 为什么它不在同类电荷元的库仑排斥作用下散开呢?
- Why does not it fly apart under the coulomb repulsion of like-charge elements? 为什么它不在同类电荷元的库仑排斥作用下散开呢?
- The competition between Coulomb repulsion and disorder produces a Coulomb glass which is an amorphous insulator. 库仑排斥与无序之间的竞争导致了一种特殊非晶绝缘体的出现,我们称之为库仑玻璃。
- Abnormal nuclei become unbound again if A>3310, because of the Coulomb repulsion. 当A>3310时反常核由于库伦能而变得非束缚。
- The Coulomb repulsion results in the potential maximum of doubly and triply diatomic ions. 指出双荷电或三荷电双原子分子离子势能极大的出现主要是来自于库仑排斥。
- The effects of the nearest neighbour Coulomb repulsion on the distribution of the charge density and the spin density are also discussed. 系统内的第三近邻电子跳跃相互作用与最近邻格点间电子Coulomb排斥相互作用之间存在着竞争。 此外,对系统中的电荷密度和自旋密度分布受最近邻格点间电子Coulomb相互作用影响情况亦进行了讨论。
- Because both qubits are positively charged, their motion is strongly coupled electrically through a phenomenon known as mutual coulomb repulsion. 由于两个量子位元都带正电,所以它们的运动状态会因为彼此的库伦斥力而有强烈的耦合。
- The numerical results of the Kondo temperature and the ground state persistent current of the system are also given under the condition that the Coulomb repulsion is infinite. 并且将它们与一级微扰变分近似所得结果进行了对比 ;指出了它们之间存在的差异 ;对于这一系统二级微扰变分近似将给出更好的数值计算结果 .
- The results show that the coulomb repulsion of electrons between nearest neighbour sites is not negligible in the calculation of superconducting transition temperature. 结果表明,相邻格点电子间的库仑排斥在计算超导转变温度时,不能忽略。
- The numerical results demonstrate that the Coulomb repulsion between the localized electrons does cause a universal gap in the single-electron density of states near the Fermi energy whose form is in reasonable agreement with our scaling predictions. 数值结果表明:库仑排斥确实导致了库仑能隙的普遍存在,单电子态密度在费米能级附近的渐近行为很好地符合我们的分析预测。
- Results show the doubly charged diatomic ions(AB(2+) )have more easy dissociation products A~+ and B~+, and they are unstable or metastable usually because of the strong Coulomb repulsion. 研究表明,双荷电的双原子分子(AB~(2+))容易离解成为两个带相同电荷的部分(A~+和B~+),在库仑力的作用下,它们通常是不稳定或亚稳定的。 对于不稳定的情况,它们的势能曲线不存在极大点和极小点,随核间距的增大单调地下降。
- In the case of H_2~+ molecule, the explosion dynamics is dominated by the bare Coulomb repulsion and it mostly proceeds in the longitudinal direction, accompanied with the radially constrained oscillations of the fragment ions. 对于氢分子离子,裸库仑力导致了库仑爆炸过程,库仑爆炸的过程主要发生在纵向,并且分离开的每个离子在管壁之间来回振荡。
- When the strengths of various couplings are changed, there will exist a critical point of the inter-site electron-electron Coulomb repulsion, and at this point, the system will experience a transformation from strong SDW state to strong SDW one. 在改变系统内有关耦合参数的情况下 ,均存在一个最近邻格点间的电子 -电子 Coulomb排斥相互作用的临界值 ,在该临界值处 ,系统将发生由强SDW态向强 CDW态的转变
- The first term is the screened Coulomb repulsion 第一项是屏蔽的库仑排斥
- It indicated that the coulombic repulsion in the former was lower than that in the latter, because a conjugation degree in the former was longer than in the latter. 发现随着分子内共轭程度的增加,分子内的库仑斥力也随之降低。
- coulomb repulsion imposes the need for high temperature 库仓斥力增添了对高温的需求。
- HIGH-T_c SUPERCONDUCTIVITY WITH THE VAN HOVE SINGULARITY INCLUDING COULOMB REPULSION 在Van Hove奇点模型下计入库仑作用的高温超导电性
- THE SUPERCONDUCTING TRANSITION TEMPERATURE AND ISOTOPE EFFECT UNDER S+D MIXED WAVE SYMMETRY INCLUDING COULOMB REPULSION AND VAN HOVE SINGULARITY s+d混合波对称性下计入库仑作用和Van Hove奇异性的超导转变温度和同位素效应