通过分别以催化剂层和纳米颗粒层分别作为底部电极和顶部电极,研究人员成功地设计了一个气体传感器并测试了其传感性能。
By employing the catalyst and nanoparticle layers as bottom and top electrodes respectively, the researchers successfully designed and tested a gas sensor.
利用计时电流法对不同光照时间纳米银颗粒组装的酶电极响应电流进行了表征。
The response current of the enzyme electrode containing AgNPs photo-induced at different time was characterized by chronoamperometry.
本发明还涉及锂金属电极,其表面覆盖金属氧化物颗粒的膜,还涉及锂金属型电池。
The invention also aims to provide a metallic lithium electrode whose surface is covered in a film of metallic oxide particles, as well as a lithium metal-type battery.
电池和模拟电极研究均表明,大颗粒硫酸铅晶体比小颗粒晶体更难还原。
The measurements of both battery and simulated electrode indicate that the large crystals are more difficult to be reduced than the small ones.
探讨纳米颗粒效应在固定化酶中所起的作用,并分析不同条件对酶电极响应灵敏度的影响。
The catalysis of enzyme improved by nanoparticles is discussed. The influence of different conditions is analyzed.
利用磁性普鲁士蓝纳米颗粒制得的修饰电极具有催化性能高、稳定性好、表面易更新等优点。
The modified electrode based on magnetic powder was renewable with the virtue of good electrocatalytic property.
镀镍层有利于贮氢合金氢化物电极大电流放电,这种作用源于微包覆过程中氢脆引起合金颗粒的细化与表面镀层增强了电极的导电性。
The rate capability of the alloys is improved after plating, due to the fine particles formed through hydrogen crisping and the nickel layer contributed to the conductivity of electrodes.
采用真空自耗电极电弧熔炼制成钕氧化物颗粒增强钛基复合材料。
The neodymide particulate reinforced titanium matrix composites were made by vacuum arc remelting.
相关金微阵列电极电镀的交流电阻抗实验也说明纳米颗粒的沉积对于降低电极体阻抗及增大表面活化处理的作用。
The relative AC impedance results also proved the deposition of platinum nanoparticles was beneficial for lower electrode body impedance and better surface activation treatment.
更具体来说,本发明涉及用于离子电渗疗法的电极组件,其包括包封在离子纳米颗粒中的药物。
In particular, there is provided an electrode structure for iontophoresis wherein a drug enclosed in ionic nanoparticles is retained.
该传感器使用金纳米颗粒层修饰的金电极为传感基底。
The sensing substrate was prepared using a gold electrode modified with a gold nanoparticle film.
实验表明,纳米颗粒可以使电极的响应电流从相应浓度的几十纳安增强到几千纳安。
The experiments show that the current response is increased from tens of nanoamperometer(nA)to thousands of nanoamperometer to the same glucose concentration.
实验表明,纳米颗粒可以使电极的响应电流从相应浓度的几十纳安增强到几千纳安。
The experiments show that the current response is increased from tens of nanoamperometer(nA)to thousands of nanoamperometer to the same glucose concentration.
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