Eucalyptus nitens: Nanomechanical properties of bark and wood fibers

Freddy Muñoz; Paulina Valenzuela; William Gacitúa

doi:10.1007/s00339-012-7014-3

Eucalyptus nitens: Nanomechanical properties of bark and wood fibers

Freddy Muñoz
, Paulina Valenzuela
, William Gacitúa

Universidad del Bío-Bío

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

In this study, Eucalyptus nitens species was nano-characterized to determine variability in nanomechanical properties within the cellular ultra-structure between the bark and wood fibers. Three factors, including site (2 levels), family (2 levels) and fiber type (bark and wood) were analyzed using three response variables, including the elastic modulus (E), hardness (H) and ductility ratio (E/H) in the middle lamella (ML) and the cell wall within the S2 layer. The results indicated significant differences for E _S2 and H _S2 when comparing fiber types: E _S2≈12.52 GPa and H _S2≈0.31 GPa for wood fiber and E _S2≈10.81 GPa and H _S2≈0.26 GPa for bark fiber. There is not statistically significant difference in ductility ratio (E/H) in S2 and ML between fiber types. These results indicate that bark and wood fibers can be used together or separately in the development of new composite materials and engineering products.

Original language	English
Pages (from-to)	1007-1014
Number of pages	8
Journal	Applied Physics A: Materials Science and Processing
Volume	108
Issue number	4
DOIs	https://doi.org/10.1007/s00339-012-7014-3
State	Published - Sep 2012

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title = "Eucalyptus nitens: Nanomechanical properties of bark and wood fibers",

abstract = "In this study, Eucalyptus nitens species was nano-characterized to determine variability in nanomechanical properties within the cellular ultra-structure between the bark and wood fibers. Three factors, including site (2 levels), family (2 levels) and fiber type (bark and wood) were analyzed using three response variables, including the elastic modulus (E), hardness (H) and ductility ratio (E/H) in the middle lamella (ML) and the cell wall within the S2 layer. The results indicated significant differences for E S2 and H S2 when comparing fiber types: E S2≈12.52 GPa and H S2≈0.31 GPa for wood fiber and E S2≈10.81 GPa and H S2≈0.26 GPa for bark fiber. There is not statistically significant difference in ductility ratio (E/H) in S2 and ML between fiber types. These results indicate that bark and wood fibers can be used together or separately in the development of new composite materials and engineering products.",

author = "Freddy Mu{\~n}oz and Paulina Valenzuela and William Gacit{\'u}a",

year = "2012",

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doi = "10.1007/s00339-012-7014-3",

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journal = "Applied Physics A: Materials Science and Processing",

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TY - JOUR

T1 - Eucalyptus nitens

T2 - Nanomechanical properties of bark and wood fibers

AU - Muñoz, Freddy

AU - Valenzuela, Paulina

AU - Gacitúa, William

PY - 2012/9

Y1 - 2012/9

N2 - In this study, Eucalyptus nitens species was nano-characterized to determine variability in nanomechanical properties within the cellular ultra-structure between the bark and wood fibers. Three factors, including site (2 levels), family (2 levels) and fiber type (bark and wood) were analyzed using three response variables, including the elastic modulus (E), hardness (H) and ductility ratio (E/H) in the middle lamella (ML) and the cell wall within the S2 layer. The results indicated significant differences for E S2 and H S2 when comparing fiber types: E S2≈12.52 GPa and H S2≈0.31 GPa for wood fiber and E S2≈10.81 GPa and H S2≈0.26 GPa for bark fiber. There is not statistically significant difference in ductility ratio (E/H) in S2 and ML between fiber types. These results indicate that bark and wood fibers can be used together or separately in the development of new composite materials and engineering products.

AB - In this study, Eucalyptus nitens species was nano-characterized to determine variability in nanomechanical properties within the cellular ultra-structure between the bark and wood fibers. Three factors, including site (2 levels), family (2 levels) and fiber type (bark and wood) were analyzed using three response variables, including the elastic modulus (E), hardness (H) and ductility ratio (E/H) in the middle lamella (ML) and the cell wall within the S2 layer. The results indicated significant differences for E S2 and H S2 when comparing fiber types: E S2≈12.52 GPa and H S2≈0.31 GPa for wood fiber and E S2≈10.81 GPa and H S2≈0.26 GPa for bark fiber. There is not statistically significant difference in ductility ratio (E/H) in S2 and ML between fiber types. These results indicate that bark and wood fibers can be used together or separately in the development of new composite materials and engineering products.

UR - https://www.scopus.com/pages/publications/84865270645

U2 - 10.1007/s00339-012-7014-3

DO - 10.1007/s00339-012-7014-3

M3 - Artículo

AN - SCOPUS:84865270645

SN - 0947-8396

VL - 108

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EP - 1014

JO - Applied Physics A: Materials Science and Processing

JF - Applied Physics A: Materials Science and Processing

IS - 4

ER -

Eucalyptus nitens: Nanomechanical properties of bark and wood fibers

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