对于适中强度的层间耦合,双层能达到静息态同步。
For interlayer coupling of moderate strength, the bilayer can achieve thesynchronization of the resting state.
这进一步证实了界面扩散是影响层间耦合的主要因素。
So it is found that the interface diffusion is a important factor influencing the AF coupling.
依据层间耦合及电声子相互作用对上述结果进行了讨论。
Discussions have been made on the above results in consideration with the coupling between layers and phonon-electron interaction.
我们发现,这两种磁序的表面模的频率随外场和层间耦合的变化情况很不同。
We find that in the voigt geometry the frequency of surface modes versus the external magnetic field and the interlayer coupling is very different in these two different magnetic orderings.
最后,我将介绍我们在二维半导体材料及其异质结构中的层间耦合和电荷传输的最新进展。
Finally, I will introduce our latest work on interlayer coupling and charge transfer in 2d atomically thin semiconductors and their heterostructures.
将超导弦孤子模型的层间耦合作用作为提高多层氧化物超导体临界温度的一种模写,结果表明。
The interlayer coupling of superconducting string soliton model ACTS as a description of critical temperature enhancement in multilayer oxide superconductors.
根据层间耦合作用对二维自旋涨落的抑制程度,我们确定了一个反映体系层状结构特点的特征温度T_0,并由此将低温区t。
According to the suppressing extent of interlayer coupling on the two-dimensional spin fluctuations, we determine a characteristic temperature T0, divide low temperature region t.
CICS和IMS应用程序的一个最佳实践是将3270UI支持从业务逻辑拆分出来,然后使用消息接口实现这两个层间的耦合。
A best practice for CICS and IMS applications is to split the 3270 UI support from the business logic, then couple these two layers using the message interface.
由于系统与底层基础设施间的连接是松耦合的,所以它能轻易地运行在任意IaaS层之上。
The system is decoupled from the underlying infrastructure and therefore easy to get running within any IaaS layer.
本文求出了声重波传播过程中,低热层臭氧含量振荡和温度场起伏间的耦合关系。
In the course of acoustic-gravity wave (AGW) propagation, a coupling relation between the ozone density oscillations (ODO) and temperature fluctuations (TF) in the lower thermosphere is presented.
研究了化学反应放热与流体混合运动间的耦合作用,分析了前者对可压混合层厚度、拟序结构及产物生成率等方面的影响。
The interaction of heat release and fluid dynamics is studied. The effects of the latter on the mixing growth, the coherent structure and the rate of product formed in the mixing layer are analyzed.
通道内气流湍流对流换热、壁面间辐射换热与隔热层内导热耦合求解。
The turbulent convection and wall radiation in channel and the thermal conduction in isolation layer are solved simultaneously.
MAG1和MAG2间的层间交换耦合可通过调节CL的材料和厚度而部分地优化。
The interlayer exchange coupling between MAG1 and MAG2 may be optimized, in part, by adjusting the materials and thickness of the CL.
MAG1和MAG2间的层间交换耦合可通过调节CL的材料和厚度而部分地优化。
The interlayer exchange coupling between MAG1 and MAG2 may be optimized, in part, by adjusting the materials and thickness of the CL.
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