The role of chemical transport in the brown-rot decay resistance of modified wood

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Standard

The role of chemical transport in the brown-rot decay resistance of modified wood. / Zelinka, S. L.; Ringman, R.; Pilgard, A.; Thybring, Emil Engelund; Jakes, J. E.; Richter, K.

I: International Wood Products Journal, Bind 7, Nr. 2, 2016, s. 66-70.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Zelinka, SL, Ringman, R, Pilgard, A, Thybring, EE, Jakes, JE & Richter, K 2016, 'The role of chemical transport in the brown-rot decay resistance of modified wood', International Wood Products Journal, bind 7, nr. 2, s. 66-70. https://doi.org/10.1080/20426445.2016.1161867

APA

Zelinka, S. L., Ringman, R., Pilgard, A., Thybring, E. E., Jakes, J. E., & Richter, K. (2016). The role of chemical transport in the brown-rot decay resistance of modified wood. International Wood Products Journal, 7(2), 66-70. https://doi.org/10.1080/20426445.2016.1161867

Vancouver

Zelinka SL, Ringman R, Pilgard A, Thybring EE, Jakes JE, Richter K. The role of chemical transport in the brown-rot decay resistance of modified wood. International Wood Products Journal. 2016;7(2):66-70. https://doi.org/10.1080/20426445.2016.1161867

Author

Zelinka, S. L. ; Ringman, R. ; Pilgard, A. ; Thybring, Emil Engelund ; Jakes, J. E. ; Richter, K. / The role of chemical transport in the brown-rot decay resistance of modified wood. I: International Wood Products Journal. 2016 ; Bind 7, Nr. 2. s. 66-70.

Bibtex

@article{30e1bd62bf0b43299d41bab011efb0de,
title = "The role of chemical transport in the brown-rot decay resistance of modified wood",
abstract = "Chemical modification of wood increases decay resistance but the exact mechanisms remain poorly understood. Recently, Ringman and coauthors examined established theories addressing why modified wood has increased decay resistance and concluded that the most probable cause of inhibition and/or delay of initiation of brown-rot decay is lowering the equilibrium moisture content. In another recent study, Jakes and coauthors examined moisture-induced wood damage mechanisms, including decay and fastener corrosion, and observed that these mechanisms require chemical transport through wood cell walls. They proposed that chemical transport within wood cell walls is controlled by a moisture-induced glass transition in interconnected networks of hemicelluloses and amorphous cellulose. This paper shows how these models jointly suggest mechanisms by which wood modifications can inhibit brown-rot. Alternative mechanisms are also discussed. These models can be used to understand and further improve the performance of wood modification systems.",
keywords = "Wood modification, Brown-rot decay, Diffusion, Chemical transport, Percolation theory, Glass transition temperature",
author = "Zelinka, {S. L.} and R. Ringman and A. Pilgard and Thybring, {Emil Engelund} and Jakes, {J. E.} and K. Richter",
year = "2016",
doi = "10.1080/20426445.2016.1161867",
language = "English",
volume = "7",
pages = "66--70",
journal = "International Wood Products Journal",
issn = "2042-6445",
publisher = "Taylor & Francis",
number = "2",

}

RIS

TY - JOUR

T1 - The role of chemical transport in the brown-rot decay resistance of modified wood

AU - Zelinka, S. L.

AU - Ringman, R.

AU - Pilgard, A.

AU - Thybring, Emil Engelund

AU - Jakes, J. E.

AU - Richter, K.

PY - 2016

Y1 - 2016

N2 - Chemical modification of wood increases decay resistance but the exact mechanisms remain poorly understood. Recently, Ringman and coauthors examined established theories addressing why modified wood has increased decay resistance and concluded that the most probable cause of inhibition and/or delay of initiation of brown-rot decay is lowering the equilibrium moisture content. In another recent study, Jakes and coauthors examined moisture-induced wood damage mechanisms, including decay and fastener corrosion, and observed that these mechanisms require chemical transport through wood cell walls. They proposed that chemical transport within wood cell walls is controlled by a moisture-induced glass transition in interconnected networks of hemicelluloses and amorphous cellulose. This paper shows how these models jointly suggest mechanisms by which wood modifications can inhibit brown-rot. Alternative mechanisms are also discussed. These models can be used to understand and further improve the performance of wood modification systems.

AB - Chemical modification of wood increases decay resistance but the exact mechanisms remain poorly understood. Recently, Ringman and coauthors examined established theories addressing why modified wood has increased decay resistance and concluded that the most probable cause of inhibition and/or delay of initiation of brown-rot decay is lowering the equilibrium moisture content. In another recent study, Jakes and coauthors examined moisture-induced wood damage mechanisms, including decay and fastener corrosion, and observed that these mechanisms require chemical transport through wood cell walls. They proposed that chemical transport within wood cell walls is controlled by a moisture-induced glass transition in interconnected networks of hemicelluloses and amorphous cellulose. This paper shows how these models jointly suggest mechanisms by which wood modifications can inhibit brown-rot. Alternative mechanisms are also discussed. These models can be used to understand and further improve the performance of wood modification systems.

KW - Wood modification

KW - Brown-rot decay

KW - Diffusion

KW - Chemical transport

KW - Percolation theory

KW - Glass transition temperature

U2 - 10.1080/20426445.2016.1161867

DO - 10.1080/20426445.2016.1161867

M3 - Journal article

VL - 7

SP - 66

EP - 70

JO - International Wood Products Journal

JF - International Wood Products Journal

SN - 2042-6445

IS - 2

ER -

ID: 168453417