Abstract:The mechanical properties and the point defect energy of magnesium hydroxide (Mg(OH)₂) were studied using the molecular dynamics. Moreover, the microelectronic structure of Mg(OH)₂ with point defects in the bulk and on its surface were investigated using the first principles. The simulation results indicate that Mg(OH)₂ was easily modified by other cations because of its strong, favorable interstitial and substitution defects via point defect energy calculation. Mg(OH)₂ can provide high-efficiency flame retardancy because of the strong OH (OH Schottky defect) or H bond (H Frenkel defect and Schottky defect). The potential model of Mg(OH)₂ was established, and molecular dynamics simulation was used to investigate the relations between the crystal structure and the mechanical properties. Mg(OH)₂ with special morphology such as nano-sheets was a prior consideration to maintain the composite mechanical properties. The detailed electronic structures of Mg(OH)₂ with defects were determined. This work may provide theoretical guidance for choosing dopant element and reveal the element doping mechanism of Mg(OH)₂.

Key words: Mg(OH)₂; density functional theory; molecular dynamics; defects; electronic structure