在层状结构材料中嵌入锂离子,体系总能量降低。
The total energy of the layered material decreases after intercalation lithium.
在许多的实际设计中,由不同压电材料和弹性材料构成的层状压电结构被广泛地采用。
In many practical devices, the layered structures consist of the piezoelectric and other materials are most widely adopted.
XRD分析表明,制得的正极材料具有完整的层状结构。
XRD results show that the prepared cathode materials have perfect layer structure.
结果表明,所有前驱物材料均能形成完整的层状水滑石结构;
The results showed that complete layer structure of hydrotalcite was formed in all precursors.
本论文利用水滑石层状结构特点和层间离子的可交换性,将其作为选择性红外吸收材料。
This thesis selects hydrotalcite as selective IR absorption material by its characters of layer and ion-exchangeable.
并对层状复合材料的成分和微观结构进行分析。
The chemical composition and microstructure of the composites were analyzed .
主要介绍了无机层状材料的结构、插层的方法、插层产物的表征等。
The structure of inorganic layered materials, the ways of intercalation and the characterization of the layered material were introduced.
本实用新型涉及一种静态层状结构的天然大理石花岗石复合拼块,属新型建筑装饰材料。
The utility model relates to a natural marble and granite compound splicing block with a static layer structure, which belongs to a novel architectural decorative material.
本文引入了用于研究结构与地基非线性动力相互作用时,对其接触面进行模型化的由层状弹塑性材料构成的有限薄层连接元法。
A thin layer joint finite element is introduced for modelling of the interfaces between structure and soil in the analysis of nonlinear dynamic interaction.
多种材料可以沉积在彼此的上面,从而在所述物体上形成层状结构。
Multiple materials can be deposited, on top of one another, forming layered structures on the object.
蒙脱土特殊的层状结构使得利用熔融共混在机械力的作用下插层到纳米级复合材料成为可能。
The lamellar structure of montmorillonite makes it possible to intercalate PA 6 into the nanocomposites under the action of mechanical force during the melt blending process.
这个算法可用于分析任意构形的冲击物对任意构形的复合材料层状结构低速冲击的响应.用该算法分析了层板的冲击响应,并预报分层损伤.预报的损伤与实验结果基本符合。
The analysis of impact responses and the prediction of impact damage have been carried out. Good agreement can be observed by the comparison of the experimental results with the numerical ones.
有效地提高了蒙脱土固体酸催化剂的热稳定性;通过从二维层状结构到三维孔道结构转变,切实提高了材料自身择形催化的特性。
We effectively improve the MMT thermal stability of solid acid catalyst and the shape-selective catalysis by transforming the two-dimensional layered structure to the three-dimensional pore structure.
有效地提高了蒙脱土固体酸催化剂的热稳定性;通过从二维层状结构到三维孔道结构转变,切实提高了材料自身择形催化的特性。
We effectively improve the MMT thermal stability of solid acid catalyst and the shape-selective catalysis by transforming the two-dimensional layered structure to the three-dimensional pore structure.
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