The Effect of Acetylation on Iron Uptake and Diffusion in Water Saturated Wood Cell Walls and Implications for Decay

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The Effect of Acetylation on Iron Uptake and Diffusion in Water Saturated Wood Cell Walls and Implications for Decay. / Zelinka, Samuel L.; Houtman, Carl J.; Hirth, Kolby; Lacher, Steven; Lorenz, Linda; Thybring, Emil Engelund; Hunt, Christopher G.

I: Forests, Bind 11, Nr. 10, 1121, 21.10.2020.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Zelinka, SL, Houtman, CJ, Hirth, K, Lacher, S, Lorenz, L, Thybring, EE & Hunt, CG 2020, 'The Effect of Acetylation on Iron Uptake and Diffusion in Water Saturated Wood Cell Walls and Implications for Decay', Forests, bind 11, nr. 10, 1121. https://doi.org/10.3390/f11101121

APA

Zelinka, S. L., Houtman, C. J., Hirth, K., Lacher, S., Lorenz, L., Thybring, E. E., & Hunt, C. G. (2020). The Effect of Acetylation on Iron Uptake and Diffusion in Water Saturated Wood Cell Walls and Implications for Decay. Forests, 11(10), [1121]. https://doi.org/10.3390/f11101121

Vancouver

Zelinka SL, Houtman CJ, Hirth K, Lacher S, Lorenz L, Thybring EE o.a. The Effect of Acetylation on Iron Uptake and Diffusion in Water Saturated Wood Cell Walls and Implications for Decay. Forests. 2020 okt. 21;11(10). 1121. https://doi.org/10.3390/f11101121

Author

Zelinka, Samuel L. ; Houtman, Carl J. ; Hirth, Kolby ; Lacher, Steven ; Lorenz, Linda ; Thybring, Emil Engelund ; Hunt, Christopher G. / The Effect of Acetylation on Iron Uptake and Diffusion in Water Saturated Wood Cell Walls and Implications for Decay. I: Forests. 2020 ; Bind 11, Nr. 10.

Bibtex

@article{4b37b69cb2fe4c2396f4fc4dca0315a8,
title = "The Effect of Acetylation on Iron Uptake and Diffusion in Water Saturated Wood Cell Walls and Implications for Decay",
abstract = "Acetylation is widely used as a wood modification process that protects wood from fungal decay. The mechanisms by which acetylation protects wood are not fully understood. With these experiments, we expand upon the literature and test whether previously observed differences in iron uptake by wood were a result of decreased iron binding capacity or slower diffusion. We measured the concentration of iron in 2 mm thick wood sections at 0, 10, and 20% acetylation as a function of time after exposure to iron solutions. The iron was introduced either strongly chelated with oxalate or weakly chelated with acetate. The concentrations of iron and oxalate in solution were chosen to be similar to those found during brown rot decay, while the concentration of iron and acetate matched previous work. The iron content of oxalate-exposed wood increased only slightly and was complete within an hour, suggesting little absorption and fast diffusion, or only slight surface adsorption. The increase in iron concentration from acetate solutions with time was consistent with Fickian diffusion, with a diffusion coefficient on the order of 10−16 m2 s−1. The rather slow diffusion rate was likely due to significant binding of iron within the wood cell wall. The diffusion coefficient did not depend on the acetylation level; however, the capacity for iron absorption from acetate solution was greatly reduced in the acetylated wood, likely due to the loss of OH groups. We explored several hypotheses that might explain why the diffusion rate appears to be independent of the acetylation level and found none of them convincing. Implications for brown rot decay mechanisms and future research are discussed.",
author = "Zelinka, {Samuel L.} and Houtman, {Carl J.} and Kolby Hirth and Steven Lacher and Linda Lorenz and Thybring, {Emil Engelund} and Hunt, {Christopher G.}",
year = "2020",
month = oct,
day = "21",
doi = "10.3390/f11101121",
language = "English",
volume = "11",
journal = "Forests",
issn = "1999-4907",
publisher = "M D P I AG",
number = "10",

}

RIS

TY - JOUR

T1 - The Effect of Acetylation on Iron Uptake and Diffusion in Water Saturated Wood Cell Walls and Implications for Decay

AU - Zelinka, Samuel L.

AU - Houtman, Carl J.

AU - Hirth, Kolby

AU - Lacher, Steven

AU - Lorenz, Linda

AU - Thybring, Emil Engelund

AU - Hunt, Christopher G.

PY - 2020/10/21

Y1 - 2020/10/21

N2 - Acetylation is widely used as a wood modification process that protects wood from fungal decay. The mechanisms by which acetylation protects wood are not fully understood. With these experiments, we expand upon the literature and test whether previously observed differences in iron uptake by wood were a result of decreased iron binding capacity or slower diffusion. We measured the concentration of iron in 2 mm thick wood sections at 0, 10, and 20% acetylation as a function of time after exposure to iron solutions. The iron was introduced either strongly chelated with oxalate or weakly chelated with acetate. The concentrations of iron and oxalate in solution were chosen to be similar to those found during brown rot decay, while the concentration of iron and acetate matched previous work. The iron content of oxalate-exposed wood increased only slightly and was complete within an hour, suggesting little absorption and fast diffusion, or only slight surface adsorption. The increase in iron concentration from acetate solutions with time was consistent with Fickian diffusion, with a diffusion coefficient on the order of 10−16 m2 s−1. The rather slow diffusion rate was likely due to significant binding of iron within the wood cell wall. The diffusion coefficient did not depend on the acetylation level; however, the capacity for iron absorption from acetate solution was greatly reduced in the acetylated wood, likely due to the loss of OH groups. We explored several hypotheses that might explain why the diffusion rate appears to be independent of the acetylation level and found none of them convincing. Implications for brown rot decay mechanisms and future research are discussed.

AB - Acetylation is widely used as a wood modification process that protects wood from fungal decay. The mechanisms by which acetylation protects wood are not fully understood. With these experiments, we expand upon the literature and test whether previously observed differences in iron uptake by wood were a result of decreased iron binding capacity or slower diffusion. We measured the concentration of iron in 2 mm thick wood sections at 0, 10, and 20% acetylation as a function of time after exposure to iron solutions. The iron was introduced either strongly chelated with oxalate or weakly chelated with acetate. The concentrations of iron and oxalate in solution were chosen to be similar to those found during brown rot decay, while the concentration of iron and acetate matched previous work. The iron content of oxalate-exposed wood increased only slightly and was complete within an hour, suggesting little absorption and fast diffusion, or only slight surface adsorption. The increase in iron concentration from acetate solutions with time was consistent with Fickian diffusion, with a diffusion coefficient on the order of 10−16 m2 s−1. The rather slow diffusion rate was likely due to significant binding of iron within the wood cell wall. The diffusion coefficient did not depend on the acetylation level; however, the capacity for iron absorption from acetate solution was greatly reduced in the acetylated wood, likely due to the loss of OH groups. We explored several hypotheses that might explain why the diffusion rate appears to be independent of the acetylation level and found none of them convincing. Implications for brown rot decay mechanisms and future research are discussed.

U2 - 10.3390/f11101121

DO - 10.3390/f11101121

M3 - Journal article

VL - 11

JO - Forests

JF - Forests

SN - 1999-4907

IS - 10

M1 - 1121

ER -

ID: 250226545