Interpreting dynamic vapor sorption (DVS) measurements: Why wood science needs to hit the reset button

Publikation: KonferencebidragPaperForskning

Standard

Interpreting dynamic vapor sorption (DVS) measurements : Why wood science needs to hit the reset button. / Zelinka, Samuel L.; Thybring, Emil E.; Glass, Samuel V.

2021. Paper præsenteret ved World Conference on Timber Engineering, Santiago, Chile.

Publikation: KonferencebidragPaperForskning

Harvard

Zelinka, SL, Thybring, EE & Glass, SV 2021, 'Interpreting dynamic vapor sorption (DVS) measurements: Why wood science needs to hit the reset button', Paper fremlagt ved World Conference on Timber Engineering, Santiago, Chile, 09/08/2021 - 12/08/2021. <https://www.fs.usda.gov/treesearch/pubs/62979>

APA

Zelinka, S. L., Thybring, E. E., & Glass, S. V. (2021). Interpreting dynamic vapor sorption (DVS) measurements: Why wood science needs to hit the reset button. Paper præsenteret ved World Conference on Timber Engineering, Santiago, Chile. https://www.fs.usda.gov/treesearch/pubs/62979

Vancouver

Zelinka SL, Thybring EE, Glass SV. Interpreting dynamic vapor sorption (DVS) measurements: Why wood science needs to hit the reset button. 2021. Paper præsenteret ved World Conference on Timber Engineering, Santiago, Chile.

Author

Zelinka, Samuel L. ; Thybring, Emil E. ; Glass, Samuel V. / Interpreting dynamic vapor sorption (DVS) measurements : Why wood science needs to hit the reset button. Paper præsenteret ved World Conference on Timber Engineering, Santiago, Chile.7 s.

Bibtex

@conference{efadbfa09c9a4fec8ed5dffdf48c3184,
title = "Interpreting dynamic vapor sorption (DVS) measurements: Why wood science needs to hit the reset button",
abstract = "Water vapor sorption is an important characteristic of wood as an engineering material. In addition to affecting engineering properties such as the heat capacity, thermal conductivity, strength, stiffness, and dimensions, moisture is fundamental to many wood degradation mechanisms including fungal decay. Water vapor sorption isotherms have been gaining increasing attention in the wood literature as more laboratories adopt automated sorption balances, frequently called dynamic vapor sorption (DVS) analyzers. With DVS, the collection of sorption isotherms can be automated, completely transforming what was once a series of tedious manual measurements. The adoption of DVS, however, preceded careful studies of the precision and accuracy of the measurement; as a result, many of the previously published studies have been cast under scrutiny in recent years as the technique has been further studied. This paper summarizes the advancements in understanding of the relationship between experimental method and experimental errors with DVS along with best practices that should be used when collecting DVS data in future studies.",
keywords = "Dynamic vapor sorption analyzers, Parallel exponential kinetics (PEK model), Water vapor sorption isotherms, Wood-moisture relations",
author = "Zelinka, {Samuel L.} and Thybring, {Emil E.} and Glass, {Samuel V.}",
note = "Publisher Copyright: {\textcopyright} WCTE 2021. All rights reserved.; World Conference on Timber Engineering 2021, WCTE 2021 ; Conference date: 09-08-2021 Through 12-08-2021",
year = "2021",
language = "English",

}

RIS

TY - CONF

T1 - Interpreting dynamic vapor sorption (DVS) measurements

T2 - World Conference on Timber Engineering 2021, WCTE 2021

AU - Zelinka, Samuel L.

AU - Thybring, Emil E.

AU - Glass, Samuel V.

N1 - Publisher Copyright: © WCTE 2021. All rights reserved.

PY - 2021

Y1 - 2021

N2 - Water vapor sorption is an important characteristic of wood as an engineering material. In addition to affecting engineering properties such as the heat capacity, thermal conductivity, strength, stiffness, and dimensions, moisture is fundamental to many wood degradation mechanisms including fungal decay. Water vapor sorption isotherms have been gaining increasing attention in the wood literature as more laboratories adopt automated sorption balances, frequently called dynamic vapor sorption (DVS) analyzers. With DVS, the collection of sorption isotherms can be automated, completely transforming what was once a series of tedious manual measurements. The adoption of DVS, however, preceded careful studies of the precision and accuracy of the measurement; as a result, many of the previously published studies have been cast under scrutiny in recent years as the technique has been further studied. This paper summarizes the advancements in understanding of the relationship between experimental method and experimental errors with DVS along with best practices that should be used when collecting DVS data in future studies.

AB - Water vapor sorption is an important characteristic of wood as an engineering material. In addition to affecting engineering properties such as the heat capacity, thermal conductivity, strength, stiffness, and dimensions, moisture is fundamental to many wood degradation mechanisms including fungal decay. Water vapor sorption isotherms have been gaining increasing attention in the wood literature as more laboratories adopt automated sorption balances, frequently called dynamic vapor sorption (DVS) analyzers. With DVS, the collection of sorption isotherms can be automated, completely transforming what was once a series of tedious manual measurements. The adoption of DVS, however, preceded careful studies of the precision and accuracy of the measurement; as a result, many of the previously published studies have been cast under scrutiny in recent years as the technique has been further studied. This paper summarizes the advancements in understanding of the relationship between experimental method and experimental errors with DVS along with best practices that should be used when collecting DVS data in future studies.

KW - Dynamic vapor sorption analyzers

KW - Parallel exponential kinetics (PEK model)

KW - Water vapor sorption isotherms

KW - Wood-moisture relations

M3 - Paper

AN - SCOPUS:85120725906

Y2 - 9 August 2021 through 12 August 2021

ER -

ID: 287573443