Title of article
Materials design in the performance of all-ceramic crowns
Author/Authors
Brian R. Lawn، نويسنده , , Antonia Pajares، نويسنده , , Yu Zhang، نويسنده , , Fei-Yan Deng، نويسنده , , Mariano A. Polack، نويسنده , , Isabel K. Lloyd، نويسنده , , E. Dianne Rekow، نويسنده , , Van P. Thompson، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2004
Pages
8
From page
2885
To page
2892
Abstract
Results from a systematic study of damage in material structures representing the basic elements of dental crowns are reported. Tests are made on model flat-layer specimens fabricated from various dental ceramic combinations bonded to dentin-like polymer substrates, in bilayer (ceramic/polymer) and trilayer (ceramic/ceramic/polymer) configurations. The specimens are loaded at their top surfaces with spherical indenters, in simulation of occlusal function. The onset of fracture is observed in situ using a video camera system mounted beneath the transparent polymer substrate. Critical loads to induce fracture and deformation at the ceramic top and bottom surfaces are measured as functions of layer thickness and contact duration. Radial cracking at the ceramic undersurface occurs at relatively low loads, especially in thinner layers. Fracture mechanics relations are used to confirm the experimental data trends, and to provide explicit dependencies of critical loads in terms of key variables: material—elastic modulus, hardness, strength and toughness; geometric—layer thicknesses and contact radius. Tougher, harder and (especially) stronger materials show superior damage resistance. Critical loads depend strongly (quadratically) on crown net thickness. The analytic relations provide a sound basis for the materials design of next-generation dental crowns.
Keywords
Dental ceramics , Crowns , Materials design , Plasticity , Radial cracks
Journal title
Biomaterials
Serial Year
2004
Journal title
Biomaterials
Record number
545470
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