• Title of article

    Structural organisation in oxide glasses from molecular dynamics modelling

  • Author/Authors

    Mountjoy، نويسنده , , Gavin and Al-Hasni، نويسنده , , Bushra M. and Storey، نويسنده , , Christopher، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2011
  • Pages
    8
  • From page
    2522
  • To page
    2529
  • Abstract
    Classical molecular dynamics modelling has been used to obtain new models of 50CaO·50P2O5 and 50MgO·50SiO2 glasses and, together with previously published models of 63CaO·37Al2O3, and 50CaO·50SiO2 glasses, these have been inspected to evaluate structural features. For the first time, models of glasses near the eutectic in three systems, aluminate, silicate, and phosphate, with the same modifier, Ca, have been compared. All have short range order which is similar to that in crystals of the same composition, 5CaO·3Al2O3, CaSiO3 and Ca(PO3)2. There is a clear trend in bonding of bridging oxygen to Ca, which is dominant in aluminate glass, common in silicate glass, and absent in phosphate glass. Preliminary results for 50MgO·50SiO2 glass show unusual behaviour because ~ 5% of oxygen is present as “non-network” oxygen, i.e. bonded only to Mg. The models show broader Qn distributions than seen in NMR experiments, and this remains an area for improvement of MD modelling of glasses. The distributions of Ca in the models have been studied using the pair distribution function TCaCa(r) which is found to be similar in the three glasses, and also similar to the previous experimental measurement for 50CaO·50SiO2 glass. The distributions of Ca are markedly different in the glasses compared to the crystals, being isotropic in the former and anisotropic in the latter, which should be a factor in glass forming ability.
  • Keywords
    Phosphate glasses , silicate glasses , Molecular dynamics , Medium range order
  • Journal title
    Journal of Non-Crystalline Solids
  • Serial Year
    2011
  • Journal title
    Journal of Non-Crystalline Solids
  • Record number

    1382315