Molecular dynamics simulations of nanoporous organosilicate glasses using Reactive Force Field (ReaxFF)

The structure and properties of nanoporous organosilicate glass (OSG) structure models with 30–70% porosities and different pore morphologies were simulated using molecular dynamics simulations with Reactive Force Field (ReaxFF) potential. The OSG structures were created from nanoporous silica struc...

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Bibliographic Details
Published inJournal of non-crystalline solids Vol. 431; no. C; pp. 103 - 111
Main Authors Rimsza, J.M., Deng, Lu, Du, Jincheng
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier B.V 01.01.2016
Elsevier
Subjects
Computer simulation
Dynamical systems
Glass
Mechanical properties
Molecular dynamics
Molecular dynamics simulations
Molecular structure
Nanoporous silica
Nanostructure
Organosilicate glass
Porosity
Reactive Force Field
Silicon dioxide
Mechanical properties
Molecular dynamics simulations
Nanoporous silica
Organosilicate glass
Reactive Force Field
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Summary:The structure and properties of nanoporous organosilicate glass (OSG) structure models with 30–70% porosities and different pore morphologies were simulated using molecular dynamics simulations with Reactive Force Field (ReaxFF) potential. The OSG structures were created from nanoporous silica structures generated using classical molecular dynamics (MD) simulations with partial charge pairwise potentials and a subsequent step of adding hydroxide and methyl groups to the dangling bonds and coordination defects. The nanoporous OSG systems were then fully relaxed using molecular dynamics simulations with ReaxFF and detailed structure analysis performed and properties calculated. Analysis of the OSG systems indicated that the structural features (bond distances and angles) as well as the Qn distribution of the nanoporous silica backbone structure are consistent with the features of dense silica and that the geometry of the added methyl groups is experimentally accurate, even after ReaxFF relaxation. The elastic modulus of the nanoporous silica was calculated and found to be 24–31GPa for system with 30% porosity and 0.5–2.5GPa for those with 70% porosity, consistent with previously reported experimental results. •MD simulations of organic/inorganic hybrid organosilicate glasses•Reactive Force Field (ReaxFF) used to treat complex bonding•Wide range of porosities introduced in OSG structures•Detailed structure and property as a function of porosity of OSG
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USDOE
13-5494
ISSN:0022-3093
1873-4812
DOI:10.1016/j.jnoncrysol.2015.04.031