Growth strategy for two-dimensional nanomaterials via a unified model

Two-dimensional (2D) materials prepared by a wet-chemical precipitation route exhibit many unique properties and high potential in various fields. Still, simple, rational and green fabrication of target materials remains challenging due to the lack of a guiding principle. Here, we propose a universal qualitative model for 2D materials grown for layered and non-layered crystal structures by wet-chemical precipitation, which is confirmed by both theoretical simulation and experimental results. It demonstrates that 2D growth can be obtained by only tuning reaction concentration and temperature. This model not only has been applied to fabricate more than 30 different 2D nanomaterials in water at room temperature in the absence of additives, but also is promising in optimizing the experimental design of numerous other 2D nanomaterials.

Impact of Mg2+ and Zn2+ Addition on the Structural, Morphological, Physicochemical, Dielectric and Biological Properties of Hydroxyapatite

In the present work, the wet-chemical precipitation technique is employed to prepare Zinc/Magnesium doped hydroxyapatite (HAP). In doped HAP, the X-ray diffraction peak shifts to a higher angle because of the contraction of the lattice parameters along a - axis. The Raman peaks at 519, 440, 1464 cm-1 indicate the presence of Mg, Zn and CO32- in doped HAP respectively. The Field Emission Scanning Electron Microscopy (FESEM) measures the grain size of pure, 5% Zn and 5% Mg doped HAP, as 275, 510, and 251 nm respectively. Transmission Electron Microscopy (TEM) confirmed the morphological change in HAP. The X-ray photoelectron spectroscopy (XPS) identifies the presence of Mg2+ and Zn2+ in doped HAP. The dopant elevates the hardness and dielectric constant, so the strength and the bone growth of HAP increases. All the doped samples show excellent antibacterial, antifungal and antibiofilm activities than the pure HAP.

Assimilation of Zinc Metal Ion With Hydroxyapatite for Impedance Studies

The aim of the present work is to examine the doping outcome of Zn metal ions on hydroxyapatite for different concentrations (0.2, 0.4, 0.6, and 0.8). The samples for the pure and Zn doped HAp are synthesized by wet chemical precipitation method. The properties and the particle size are identified by using XRD. The functional bands of PO, CO and OH are analyzed through FTIR and the surface morphology and particle shapes are studied through SEM. The elemental analysis such as zinc, calcium and phosphates are analyzed by EDAX. All the designed elements are studied and confirm the (Ca+Zn)/PO ratio is nearly 1.67 and no other elements were identified in this study. The morphological particles of needle shape and the nanoscale particle size and shapes are studied by using TEM. The electrical conductivity of the synthesized ZnHAp ceramic is mainly related to width of the channel and the polarizability. The frequency dependence of the electric and dielectric properties was studied by using impedance spectroscopy.

Assimilation of Zinc Metal Ion With Hydroxyapatite for Formation and Dielectric Studies

The aim of the present work is to investigate the doping effect of Zn metal ions on hydroxyapatite for different concentrations (0.2, 0.4, 0.6, and 0.8). The samples for the pure and Zn doped HAp are synthesized by wet chemical precipitation method. The properties and the particle size are identified by using XRD. The functional bands of PO, CO and OH are analyzed through FTIR and the surface morphology and particle shapes are studied through SEM. The elemental analysis such as zinc, calcium and phosphates are analyzed by EDAX. All the designed elements are studied and confirm the (Ca+Zn)/PO ratio is nearly 1.67 and no other elements were identified in this study. The morphological particles of needle shape and the nanoscale particle size and shapes are studied by using TEM. The electrical conductivity of the synthesized ZnHAp ceramic is mainly related to width of the channel and the polarizability. The dielectric loss and nyquist plots were studied by using impedance spectroscopy.

Green Chemistry Synthesis of Nano-Hydroxyapatite : Effect of Natural Stabilisers on Ca/P

Present work described the effect of natural stabilizers on Ca/P on naturally synthesised and Eco-friendly Nano-HAP powders.Nano- powders were preparedemploying wet chemical precipitation method by adjusting Ca/P between 1.5 to2.2,using different Natural Stabilisers (NSs)such as Rice Water (RcW), Soya Milk (SM), Tea Decoction (TD), Tulsi Leaves (TL), Soya Leaves (SL), Rose Petals (RP), Spinach Leaves (SpL), Gum Kondagogu (GKg) and Aloe Vera (AlV)as precursors. The pH of the powders was varying from 8.1 to 12.8.In this paper, the average crystallite sizes of the samples, pH, therate of reaction, initial temperature and Ca/P of synthesised powders are reported.