Identification of stiffness tensor components of wood cell walls by means of nanoindentation

Composites Part A: Applied Science and Manufacturing

Volumn 42, Issue 12, 2011, Pages 2101-2109

  Jager A ^a   Hofstetter, K ^a   Buksnowitz, Ch ^b   Gindl Altmutter, W ^b   Konnerth, J ^b  

^a VIENNA UNIVERSITY OF TECHNOLOGY   (Austria)

^b UNIVERSITY OF NATURAL RESOURCES AND LIFE SCIENCES   (Austria)

Author keywords

A. Wood; B. Anisotropy; B. Mechanical properties; C. Analytical modeling

Indexed keywords

A. WOOD; ANALYTICAL MODELING; B. ANISOTROPY; B. MECHANICAL PROPERTIES; CELL WALLS; CELLULOSE MICROFIBRILS; ELASTIC MATERIALS; ERROR MINIMIZATION; EXPERIMENTAL SETUP; HIGH VARIABILITY; HIGHLY SENSITIVE; INDENTATION MODULUS; LOCAL ORIENTATIONS; LONGITUDINAL MODULUS; MICRON SCALE; NANOINDENTATION EXPERIMENTS; NATURAL MATERIALS; STIFFNESS TENSOR; TRANSVERSE MODULUS; WOOD CELL WALLS;

ANISOTROPY; BIOMECHANICS; CELLS; CELLULOSE; CELLULOSE DERIVATIVES; ELASTIC MODULI; ELASTICITY; NANOINDENTATION;

WOOD;

ANISOTROPY; CELL WALLS; CELLS; CELLULOSE DERIVATIVES; ELASTIC STRENGTH; ELASTICITY; MECHANICAL PROPERTIES; SHEAR STRENGTH; WOOD;

EID: 80055070135     PISSN: 1359835X     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.compositesa.2011.09.020     Document Type: Article

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