Synthesis and optical properties of Mg-doped ZnO nanofibers prepared by electrospinning

“…The Raman peak at 436.8 cm −1 is attributed to the E 2 (H) mode, which is one of the characteristic peaks of wurtzite structure of ZnO [62]. The peak located at 575 cm −1 is corresponding to E 1 (LO) mode, which is usually ascribed to the formation of the defects such as oxygen vacancy and Zn interstitial [29,63,64]. Since the nanoparticles were casually dispersed on the sample holder for the Raman measurement, the quantity and thickness distribution of three samples were not exactly same during the measurement.…”

Tunable deep-level emission in ZnO nanoparticles via yttrium doping

“…The Raman peak at 436.8 cm −1 is attributed to the E 2 (H) mode, which is one of the characteristic peaks of wurtzite structure of ZnO [62]. The peak located at 575 cm −1 is corresponding to E 1 (LO) mode, which is usually ascribed to the formation of the defects such as oxygen vacancy and Zn interstitial [29,63,64]. Since the nanoparticles were casually dispersed on the sample holder for the Raman measurement, the quantity and thickness distribution of three samples were not exactly same during the measurement.…”

Tunable deep-level emission in ZnO nanoparticles via yttrium doping

“…Raman spectroscopy is a versatile technique for fast and nondestructive study of phonon scattering processes in materials. The Raman spectra of Mg-doped ZnO nanostructures were reported [8][9][10]. However, the influence of Mg doping on the lattice dynamics of ZnO was rarely discussed in detail.…”

Structure and Raman scattering of Mg-doped ZnO nanoparticles prepared by sol–gel method

“…Recently, one-dimensional nanostructures are of increasing interest because of their unique electrical, physical, and optical properties, and various applications, such as catalysts, electronics, optics, biodiagnostics, and energy storage devices [5,6]. For energy devices, electrochemical capacitors have been fabricated using different one-dimensional nanostructures.…”

Preparation and characterization of electro-spun RuO2–Ag2O composite nanowires for electrochemical capacitors