Structure-property relationships in thermally aged cellulose fibers and paper

Kato, Kazushige; Cameron, Ruth E.

doi:10.1002/(sici)1097-4628(19991107)74:6<1465::aid-app20>3.0.co;2-3

Cited by 39 publications

(21 citation statements)

References 12 publications

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“…From these results, the crystallization of cellulose can be concluded to be a minor mechanism for the enhancing effects of ageing. Other possible mechanisms include hornification [9], the cross-linking reaction in lignin, and the rearrangement of disordered polysaccharides, but those hypotheses require further experimentation.…”

Section: Introductionmentioning

confidence: 82%

Effects of natural and artificial ageing on the physical and acoustic properties of wood in musical instruments

Obataya

2017

Journal of Cultural Heritage

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a b s t r a c tThe reversible and irreversible effects of natural and artificial hydrothermal ageing are reviewed with respect to the hygroscopicity and acoustic properties relevant to the practical quality of wooden musical instruments. Long-term natural ageing reduces the hygroscopicity of wood while improving its acoustic quality, but these changes are partly reversible by exposure to high humidity. Similar reversible changes are observed in hydrothermally treated wood, especially when the wood is heated at an intermediate relative humidity. These reversible changes are attributed to the annealing-like rearrangement of amorphous wood polymers or the temporary closure of micropores, but further investigation is necessary. Color change resulting from natural ageing is shown to be successfully reproducible by oven-heating.

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Section: Introductionmentioning

confidence: 82%

Effects of natural and artificial ageing on the physical and acoustic properties of wood in musical instruments

Obataya

2017

Journal of Cultural Heritage

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“…They speculated that the accessibility of wood is reduced by the dehydration of amorphous wood polymers during or after the heating. In the present study, however, the EMC was recovered considerably by the moistening, whereas the term hornification is generally used for the irreversible reduction in accessibility and mobility of polymers due to drying (Kato and Cameron 1999). Therefore, the hornification is excluded from the present discussion.…”

Section: Reversible and Irreversible Changes In Hygroscopicitymentioning

confidence: 99%

Effects of heating humidity on the physical properties of hydrothermally treated spruce wood

et al. 2016

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To clarify the effects of humidity during heating on the physical properties of hydrothermally treated wood, Sitka spruce wood was heated in an autoclave at 120C and different heating humidity (HRH), and their equilibrium moisture content (EMC), specific dynamic Young's modulus (E'/), and mechanical loss tangent (tan) were measured at 25C and 60% RH before and after the hydrothermal treatment. Higher values of HRH resulted in greater loss in weight (WL) because of the acceleration of thermal degradation in the presence of moisture. The time-humidity superposition was applicable to the changes in WL. The EMC was minimized by heating at intermediate HRH (60%), but it recovered significantly after the wood was moistened at 100% RH.This fact suggested that the reduction in hygroscopicity due to hydrothermal treatment included both reversible and irreversible effects. The reversible effect was not observed when the wood was heated at 92% HRH or above. After the moistening, the EMC value of hydrothermally treated wood decreased monotonically with increasing HRH and WL. An irreversible chemical change such as decomposition of hemicelluloses was responsible for the irreversible effect, whereas the reversible effect may have resulted from the annealing of amorphous wood polymers. After hydrothermal treatment at 80% HRH or lower, E'/ increased and tan decreased mainly because of the reduction in EMC. On the other hand, high-humidity heating (92% HRH) resulted in significant decrease in E'/ and remarkable increase in tan probably because of the depolymerization of hemicelluloses.The color of wood was darkened by the hydrothermal treatment, and the CIELAB color parameters of hydrothermally treated wood were closely connected to the WL. ManuscriptClick here to download Manuscript

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“…There were two main reasons for the improvement. Firstly, hemicellulose degraded in high temperature conditions, resulting in the decrease of free hydroxyl groups, improving the dimensional stability of wood 29 . Secondly, as shown in Fig.…”

Section: Resultsmentioning

confidence: 99%

Combined effects of ZnO particle deposition and heat treatment on dimensional stability and mechanical properties of poplar wood

Cui

Zhang

et al. 2017

Sci Rep

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This study proposed a one-step wood modification method by combining the deposition of ZnO particles on wood surface and heat treatment. The effects of ZnO particles and heat treatment on mechanical properties and dimensional stability of poplar wood were examined. Samples were sorted into 4 groups, i.e., control, heat-treated, impregnation/heat-treated, and hydrothermal-treated samples. The mechanical properties and dimensional stability of impregnation/heat-treated and hydrothermal-treated wood samples were measured in comparison with those of the control and heat-treated wood samples. Compared with the control ones, the reduction of the flexural strength of the heat-treated, impregnation/heat-treated and hydrothermal-treated samples were about 11.57%, 8.53% and 15.90%, respectively. The modulus of elasticity of the heat-treated and hydrothermal-treated samples decreased by 13.78% and 23.78%, respectively, while the impregnation/heat-treated samples increased by about 8.57% due to the ZnO particles growth. The dimensional stabilities of the heat-treated, impregnated/heat-treated and hydrothermal-treated samples were improved in comparison with that of the control sample. All samples were characterized by the scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FTIR) and X - ray diffraction (XRD).

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Structure-property relationships in thermally aged cellulose fibers and paper

Cited by 39 publications

References 12 publications

Effects of natural and artificial ageing on the physical and acoustic properties of wood in musical instruments

Effects of natural and artificial ageing on the physical and acoustic properties of wood in musical instruments

Effects of heating humidity on the physical properties of hydrothermally treated spruce wood

Combined effects of ZnO particle deposition and heat treatment on dimensional stability and mechanical properties of poplar wood

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