1) dispersed phase solid electrolyte system
分散相固体电解质体系
2) solid electrolyte diffusion barrier
固体电解质扩散障
3) solid electrolyte
固体电解质
1.
Characterization of Sm_xLi_(0.5-x)Ca_(0.5)TiO_3 solid electrolytes prepared by the sol-gel technique;
溶胶-凝胶法制备固体电解质Sm_xLi_(0.5-x)Ca_(0.5)TiO_3及其性质
2.
Corrosion behavior of solid electrolyte used for evolution of oxygen in molten cryolite salt;
析氧阳极固体电解质在冰晶石中的腐蚀行为
3.
Preparation,structure and ionic conductivity of ABO_3-type solid electrolyte La_(1-x)Sr_xGa_(1-y)Mg_yO_(3α);
ABO_3型固体电解质La_(1-x)Sr_xGa_(1-y)Mg_yO_(3-α)制备与导电性
4) solid electrolytes
固体电解质
1.
Research of doped zirconia solid electrolytes;
氧化锆基固体电解质材料的掺杂研究
2.
Based on the similarities between polyelectrolytes and semi conductors,a series of single ion polyurethane solid electrolytes were prepared and a novel conductivity theory of the single ion polyurethane solid electrolytes was studied by the method of quantum mechanics.
根据聚合物固体电解质与半导体的相似性,借鉴量子力学处理半导体和离子晶体的方法,初步研究了单离子型聚氨酯固体电解质的离子传导理论。
3.
This paper gives a brief review of the development in the electrical properties of ZrO2 based solid electrolytes, with a particular emphasis on the relationship between the compositions and the electrical properties for this type of material.
本文回顾了在ZrO2基固体电解质材料电性能研究方面所取得的进展,着重对这类材料组成与电性能之间的关系进行了评述。
5) solid-electrolyte
固体电解质
1.
Research on new solid-electrolyte SO_2 gas sensor;
新型固体电解质SO_2传感器的研制
2.
Static characteristic of small hollow pipe-type solid-electrolyte CO_2 sensor;
空心管式固体电解质CO_2传感器的静态特性
3.
Development of solid-electrolyte double function gas sensor
固体电解质双功能气体传感器的研制
6) Solid polymer electrolyte
固体电解质
1.
A novel solid polymer electrolytes based on polyester-urethane elastomer with oligo-ether sulfonate as plasticizers was prepared.
结果表明,通过选取适当平均相对分子质量的磺化低聚醚以及通过控制磺化低聚醚的质量分数,可以优化聚氨酯固体电解质体系的离子导电性能。
2.
The main performance, characteristics and the market prospect of polymer lithium ion batteries are introduced as well as the solid polymer electrolyte it adopted.
介绍了聚合物锂离子蓄电池的主要性能特点 ,采用的聚合物固体电解质体系和市场前景。
补充资料:分散相固体电解质体系
分子式:
CAS号:
性质:当固体电解质中加入另一种惰性的固体微粒并成为分散体系时,其电导率可增加1~2数量级。如LiI室温下的电导率约为10-7S/cm,当其中混合适当比例Al2O3微粉时,可提高至10-5S/cm。其原因很可能与惰性微粒加入后相界面的电导增加有关。这是提高固体电解质电导率的一种方法。
CAS号:
性质:当固体电解质中加入另一种惰性的固体微粒并成为分散体系时,其电导率可增加1~2数量级。如LiI室温下的电导率约为10-7S/cm,当其中混合适当比例Al2O3微粉时,可提高至10-5S/cm。其原因很可能与惰性微粒加入后相界面的电导增加有关。这是提高固体电解质电导率的一种方法。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条