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Materials having nanoscale structures have shown potentials for applications in microelectronics, biomedicine and energy storage. A continuing challenge is the capability of fabricating multi-function nanodevices with controlled nanostructures and excellent performances. Measurement platforms, which provide accurate and detailed information on internal structures, surface morphologies, mechanical properties and electrochemical properties are a key to this challenge. In this review, we, in particular, highlight the crucial role of measurement techniques in quantifying these nanostructures and their properties.

The research used a DC sputtering system to grow indium nitride compound doped oxygen sensing film, which could be applied in the fabrication of relative humidity sensor. In this study, the design of two specific substrates, including silicon substrate and anodic aluminum oxide (AAO) substrate, were of some uses for relative humidity sensor fabrication to enhance the sensitivity. Besides, the influence of different substrates on responsivity was also explored to verify the sensing performances of indium nitride compound doped oxygen element in relative humidity sensor. The resistance response of InN:O sensing device using silicon substrate was better than that using AAO substrate. The RH adsorption and desorption time of InN:O sensing device using silicon substrate were 94 s and 35 s, respectively. The capacitance response of InN:O sensing device using AAO substrate was better than that using silicon substrate. The RH adsorption and desorption times of InN:O sensing device using AAO substrate were 289 s and 286 s respectively.

ZrO₂ is a kind of inorganic material with high hardness, high tenacity, antiwear, corrosion, and resistance, therefore it is regarded as an ideal nanolubricant material. But untreated ZrO₂ nanoparticles are reunited in the lubricant medium instead of monodisperse because the consistency is poor between the material surface and lubricant, which restricts its application as a nanolubricant additive. Through theoretical analysis, this paper designed that the surface of ZrO₂ nanoparticles was modified with silicon coupling agent, and it was changed to lipophilic surface, so it was possible to be a monodisperse system in the lubricant. The modified spherical nanoparticles of ZrO₂ were dispersed in the lubricant and they could play a molecular bearing part in lubricating media. When the friction surface reached a certain load and temperature, once the metal surface produces the deficiency, physical adsorption and chemisorption on the metal surface would be produced because of high nano-ZrO₂ particle activity, and even the N atom in the particle surface silane tends to be absorbed to the metal surface to form chelate compound, and make ZrO₂ particles enrich to defective locations of the metal surface. Then, a self-repairing lubricated membrane in the friction surfaces was set up, and it can play the function in the antifriction, antiwear, and surface dynamic self-repair.