M-Integral for calculating intensity factors of cracked piezoelectric materials using the exact boundary conditions

Journal of Applied Mechanics, Transactions ASME

Volumn 76, Issue 1, 2009, Pages 1-9

  Motola, Yael ^a   Banks Sills, Leslie ^a  

^a TEL AVIV UNIVERSITY   (Israel)

Author keywords

Boundary conditions; Electric permittivity; Finite element method; Intensity factors; M integral; Piezoelectric material

Indexed keywords

ABSOLUTE VALUES; ANALYTICAL SOLUTIONS; APPLIED LOADS; CRACK FACES; CRACK-FACE TRACTION; ELECTRIC FLUX DENSITY; ELECTRIC PERMITTIVITIES; ELECTRIC PERMITTIVITY; EXTRAPOLATION METHODS; FINITE LENGTH; FOUR-POINT BEND SPECIMEN; INTENSITY FACTORS; M-INTEGRAL; POLING DIRECTIONS;

BOUNDARY CONDITIONS; BOUNDARY ELEMENT METHOD; CRACKS; ELECTRIC FIELDS; ELECTRIC NETWORK ANALYSIS; EXTRAPOLATION; FINITE ELEMENT METHOD; MEMS; PERMITTIVITY; PIEZOELECTRIC CERAMICS; PIEZOELECTRIC DEVICES; PIEZOELECTRICITY;

ELECTRIC TRACTION;

EID: 70350248274     PISSN: 00218936     EISSN: 15289036     Source Type: Journal    
DOI: 10.1115/1.2998485     Document Type: Article

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