A Geometric Framework for the Kinematics of Crystals With Defects

Abstract

Presented is a general theoretical framework capable of describing the finite deformation kinematics of several classes of defects prevalent in metallic crystals. Our treatment relies upon powerful tools from differential geometry, including linear connections and covariant differentiation, torsion, curvature, and anholonomic spaces. A length scale dependent, three-term multiplicative decomposition of the deformation gradient is suggested, with terms representing recoverable elasticity, residual lattice deformation due to defect fields, and plastic deformation resulting from defect fluxes. Also proposed is an additional micromorphic variable representing additional degrees-of-freedom associated with rotational lattice defects (i.e. disclinations), point defects, and, most generally, Somigliana dislocations. We illustrate how particular implementations of our general framework encompass notable theories from the literature and classify particular versions of the framework via geometric terminology.

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Document Details

Document Type
Technical Report
Publication Date
Feb 01, 2006
Accession Number
ADA444720

Entities

People

  • David L. Mcdowell
  • Douglas J. Bammann
  • John D. Clayton

Organizations

  • United States Army Research Laboratory

Tags

Communities of Interest

  • Energy and Power Technologies
  • Weapons Technologies

DTIC Thesaurus Topics

  • Bravais Lattices
  • Cartesian Coordinates
  • Continuum Mechanics
  • Crystal Defects
  • Crystal Lattices
  • Crystal Structure
  • Crystals
  • Cubic Lattices
  • Curvature
  • Differential Geometry
  • Elastic Properties
  • Geometry
  • Mechanics
  • Molecular Dynamics
  • Physics
  • Plastic Deformation
  • Point Defects

Readers

  • Calculus or Mathematical Analysis
  • Materials Science and Engineering.
  • Systems Analysis and Design

Technology Areas

  • Space