Regulating interface interaction in alumina/graphene composites with nano alumina coating transition layers.

The structure and properties of graphene/alumina composites are affected by the interface interaction. To demonstrate the influence of interface interaction on the structure of composite materials, a composite without graphene/matrix alumina interface was designed and prepared. We introduced a nano transition layer into the composite by pre-fabricating nano alumina coating on the surface of graphene, thus regulating the influence of interface interaction on the structure of the composite. According to the analysis of laser micro Raman spectroscopy, the structure of graphene was not seriously damaged during the modification process, and graphene was subjected to tensile or compressive stress along the 2D plane. The fracture behavior of the modified graphene/alumina composites is similar to that of pure alumina, but significantly different from that of pure graphene/alumina composites. The elastic modulus and hardness of composite material G/A/A are higher, while its microstructure has better density and uniformity. In situ HRSEM observation showed that there was a transition layer of alumina in the modified graphene/alumina composite. The transition layer blocks or buffers the interfacial stress interaction, therefore, the composite material exhibits a fracture behavior similar to that of pure alumina at this time. This work demonstrates that interface interactions have a significant impact on the structure and fracture behavior of graphene/alumina composites.

[Research on the quantitative analysis of D2 using Raman spectroscopy].

Raman spectroscopy was used for experimental research on D2 signal to noise ratio (SNR) under different conditions. The 32 mW Ar+ laser was injected into the Raman quartz glass cells to study the effect of grating, laser power, exposure time and the gas pressure on D2 Raman spectra SNR. D2 Raman spectral signal to noise ratio is proportional to the laser power, exposure time and gas pressure. The standard curve of the pressure and SNR for this experimental apparatus was obtained. Three sets of random samples were used to verify the formula SNR(J 2 --> 2) = 10.6 x 10(-4) p+1.271 34. When the deuterium pressure is 21 280 Pa, the relative error is 4.8%. When the pressure increases to 67 235 Pa, the relative error is down to 1.46%.

[Application of laser Raman spectroscopy to hydrogen isotope analysis].

Analysis of laser Raman spectroscopy has turned into the efficient research method of substance structure and composition analysis. In the present paper, the principle of laser Raman spectroscopy and its characteristics of analysis method are introduced. Applicability of laser Raman spectroscopy to hydrogen isotope analysis is analyzed. The analytical applications of laser Raman spectroscopy method in radiation reaction of tritium, hydrogen isotope examination and quantitative analysis are presented from reported literature.