1) Sensitization
[英][,sensitai'zeiʃən] [美][,sɛnsətə'zeʃən]
敏化特性
1.
Spectral Properties and Sensitization of Ce~3+ and Eu~2+ Ions Codoped Calcium Zinc Chlorosilicate;
Ce~(3+)和Eu~(2+)共激活氯硅酸锌钙的光谱和敏化特性
2) gas sensing property
气敏特性
1.
The gas sensing property shows that the Pd-doped SnO2 nanowires have higher sense and faster response.
SnO2纳米线的气敏特性表明,掺杂了钯的SnO2纳米线对丙酮灵敏度高,响应快。
3) pulling sensitive characteristic
拉敏特性
1.
Investigation on shielding properties and pulling sensitive characteristic of complex silicone rubber filled with carbon black;
炭黑填充复合型硅橡胶屏蔽性能及拉敏特性研究
2.
Investigation on shielding properties and pulling sensitive characteristics of conductive RTV silicone rubber.;
导电型室温硫化硅橡胶的屏蔽性能及拉敏特性研究
4) humidity sensing properties
湿敏特性
1.
Research on humidity sensing properties of pan-poly-vanadium-molybdenum acid nanocomposites;
聚苯胺-复合钒钼酸纳米复合材料的湿敏特性研究
2.
The effects of the content of molybdenum, electrode materials and temperature on the humidity sensing properties of H2V12–xMoxO31± · nH2O were discussed.
采用sol-gel法制备复合钒钼酸H2V12–xMoxO31±y·nH2O(0≤x≤4)干凝胶薄膜并研究了Mo含量、电极及温度等对其湿敏特性的影响。
3.
The humidity sensing properties of the thin films are good in the relative humidity range 11%~95%,the response time and the recovery time are 6 s and 15 s,the temperature error of the humidity is 0.
nH2O)干凝胶薄膜,薄膜为层状结构,V和Mo分别以V5+和Mo6+存在;在11%~95%RH的范围内,复合钒钼酸干凝胶薄膜具有很好的湿敏特性,响应、恢复时间分别为6s和15s,感湿温度系数为0。
5) oxygen sensitivity
氧敏特性
1.
Surface characteristics and oxygen sensitivity of TiO_2 doped by Mo~(6+);
Mo~(6+)掺杂TiO_2纳米材料的表面性能及氧敏特性
2.
the oxygen sensitivity of the film is discussed mainly.
以 L a(NO3) 3· 6 H2 O和 Ni(NO3) 2 · 6 H2 O为原料 ,采用柠檬酸为螯合剂 ,利用溶胶 -凝胶法合成了钙钛矿型稀土复合氧化物 L a Ni O3纳米陶瓷薄膜 ,研究了薄膜的氧敏特性及烧成温度和掺杂对薄膜氧敏特性的影
3.
Oxygen sensitivity of the film was discussed mainly and the effect of sintering temperature on the oxygen sensitivity was also studied.
本文以La(NO_3)_3·6H_2O和Ni(NO_3)_2·6H_2O为配位前驱体,采用柠檬酸为螯合剂,利用溶胶-凝胶法合成了钙钛矿型稀土复合氧化物LaNiO_3薄膜,研究了薄膜的氧敏特性及烧结温度对薄膜氧敏特性的影响。
补充资料:正温度系数热敏陶瓷阻-温特性曲线
分子式:
CAS号:
性质:描述正温度系数热敏陶瓷电阻率与温度关系的曲线。钛酸钡基PTC热敏陶瓷阻-温特性曲线。电阻率随着温度的升高,先是降低,当达到某一值Tmin时,曲线出现极值,经过极值后电阻率随温度升高而急剧上升,此时对应的温度Tb称为开关温度。电阻率随温度上升达到最大值时所对应的温度为Tm。经过Tm后,阻温特性曲线发生弯曲,电阻率开始逐步降低,此时对应的温度为Tp。温度处于Tb至Tm之间时,热敏陶瓷呈现正温度系数(PTC)特性。其电阻温度系数αT= ,式中Rb,Rp为Tb,Tp温度下的相 应零功率电阻值。αT大于10%/℃,为开关型热敏陶瓷电阻器。αT小于10%/℃,为缓变型热敏陶瓷电阻器。
CAS号:
性质:描述正温度系数热敏陶瓷电阻率与温度关系的曲线。钛酸钡基PTC热敏陶瓷阻-温特性曲线。电阻率随着温度的升高,先是降低,当达到某一值Tmin时,曲线出现极值,经过极值后电阻率随温度升高而急剧上升,此时对应的温度Tb称为开关温度。电阻率随温度上升达到最大值时所对应的温度为Tm。经过Tm后,阻温特性曲线发生弯曲,电阻率开始逐步降低,此时对应的温度为Tp。温度处于Tb至Tm之间时,热敏陶瓷呈现正温度系数(PTC)特性。其电阻温度系数αT= ,式中Rb,Rp为Tb,Tp温度下的相 应零功率电阻值。αT大于10%/℃,为开关型热敏陶瓷电阻器。αT小于10%/℃,为缓变型热敏陶瓷电阻器。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
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