Skip navigation
Skip navigation
A change is coming. Click to see a sneak peek of the new Open Research Repository.

Atomic scale modelling of the cores of dislocations in complex materials part 2: applications

link to publisher version

  • Altmetric Citations

Walker, Andrew; Gale, Julian D; Slater, Ben; Wright, Kate

Description

In an accompanying article, we have described a methodology for the simulation of dislocations in structurally complex materials. We illustrate the applicability of this method through studies of screw dislocations in a structurally simple ionic ceramic (MgO), a molecular ionic mineral (forsterite, Mg2SiO4), a semi-ionic zeolite (siliceous zeolite A) and a covalent molecular crystalline material (the pharmaceutical, orthorhombic paracetamol-II). We focus on the extent of relaxation and the...[Show more]

dc.contributor.authorWalker, Andrew
dc.contributor.authorGale, Julian D
dc.contributor.authorSlater, Ben
dc.contributor.authorWright, Kate
dc.date.accessioned2015-12-13T22:52:02Z
dc.date.available2015-12-13T22:52:02Z
dc.identifier.issn1463-9076
dc.identifier.urihttp://hdl.handle.net/1885/81369
dc.description.abstractIn an accompanying article, we have described a methodology for the simulation of dislocations in structurally complex materials. We illustrate the applicability of this method through studies of screw dislocations in a structurally simple ionic ceramic (MgO), a molecular ionic mineral (forsterite, Mg2SiO4), a semi-ionic zeolite (siliceous zeolite A) and a covalent molecular crystalline material (the pharmaceutical, orthorhombic paracetamol-II). We focus on the extent of relaxation and the structure of the dislocation cores and comment on similarities and points of disparity between these materials. It is found that the magnitude of the relaxation varies from material to material and does not simply correlate with the magnitude of the principal elastic constants in an easily predictable fashion, or with the size of the cohesive lattice energy or length of the Burgers vector, which emphasises the need to model the non-linear forces and atomic structure of the core.
dc.publisherRoyal Society of Chemistry
dc.sourcePhysical Chemistry Chemical Physics
dc.subjectKeywords: magnesium orthosilicate; magnesium oxide; magnesium silicate; paracetamol; silicon derivative; zeolite; article; biomedical engineering; ceramics; chemical model; chemistry; crystallization; materials; methodology; nanotechnology; Acetaminophen; Biomedica
dc.titleAtomic scale modelling of the cores of dislocations in complex materials part 2: applications
dc.typeJournal article
local.description.notesImported from ARIES
local.description.refereedYes
local.identifier.citationvolume7
dc.date.issued2005
local.identifier.absfor040306 - Mineralogy and Crystallography
local.identifier.absfor030307 - Theory and Design of Materials
local.identifier.ariespublicationMigratedxPub9671
local.type.statusPublished Version
local.contributor.affiliationWalker, Andrew, College of Physical and Mathematical Sciences, ANU
local.contributor.affiliationGale, Julian D, Curtin University of Technology
local.contributor.affiliationSlater, Ben, Royal Institution of Great Britain
local.contributor.affiliationWright, Kate, Curtin University of Technology
local.bibliographicCitation.startpage3235
local.bibliographicCitation.lastpage3242
local.identifier.doi10.1039/b505716g
dc.date.updated2015-12-11T10:48:35Z
local.identifier.scopusID2-s2.0-25444499689
CollectionsANU Research Publications

Download

There are no files associated with this item.
Show simple item record


Items in Open Research are protected by copyright, with all rights reserved, unless otherwise indicated.

Updated:  17 November 2022/ Responsible Officer:  University Librarian/ Page Contact:  Library Systems & Web Coordinator