Structural differences between reaction wood and opposite wood with different drying temperatures

Reaction wood is characterized by having different anatomical and chemical features than normal wood. The different composition of cell walls, the higher quantitative proportion of thick-wall fiber cells, diameter, and the abundance of vessels have remarkable effects on reaction wood’s physical and mechanical properties. Reaction wood has fewer vascular cells. In addition, it has a smaller lumen diameter, which results in reduced permeability. Therefore, reaction wood is more difficult to dry at a certain moisture content. The differences in the drying times of the reaction wood and the normal wood were largest at a temperature of 60 °C and durations greater than 30 h, and the reaction wood dried more slowly. At a temperature of 120 °C, the differences in drying time were minimalized, and drying end times were almost identical. The expected negative effect of higher temperature on the morphology of reaction wood and opposition wood was not confirmed.

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QUALITY OF REACTION WOOD IN Eucalyptus TREES TILTED BY WIND FOR PULP PRODUCTION

CERNE ◽

10.1590/01047760201723032286 ◽

2017 ◽

Vol 23 (3) ◽

pp. 291-297

Author(s):

Walter Torezani Neto Boschetti ◽

Juarez Benigno Paes ◽

Graziela Baptista Vidaurre ◽

Marina Donária Chaves Arantes ◽

João Gabriel Missia da Silva

Keyword(s):

Chemical Composition ◽

Chemical Constituents ◽

Wood Quality ◽

Basic Density ◽

Kraft Pulping ◽

Normal Wood ◽

Reaction Wood ◽

Opposite Wood ◽

Holocellulose Content

ABSTRACT This study aims to evaluate the quality of normal, tension and opposite wood of eucalyptus trees lengthwise, in straight and inclined stems, affected by wind action. It also aims to explain the pulping parameters resultant from the quality of the wood. The trees were grouped into four tilt ranges, ranging from 0 to 50º, and the basic density, chemical composition of the wood, and performance in kraft pulping were assessed. Normal and tension wood had similar basic densities; while for opposite wood, the density was lower, being responsible for a decrease in reaction wood density. The chemical composition of the wood was influenced by the presence of reaction wood in the stem. Tension and opposite wood showed lower levels of extractives and lignin and higher holocellulose content when compared to normal wood, with favorable wood quality for pulping. The increase in holocellulose content and the reduction of lignin and extractives content contributed positively to a more delignified pulp and reduction of the Kappa number. However, after cooking the reaction wood under the same conditions as those of normal wood, reaction wood pulping tends to have a lower screen yields. Due to differences in basic density and chemical constituents between opposite and normal wood, it is recommended not to designate the opposite wood as normal wood.

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Influência do lenho de tração nas propriedades físicas da madeira de Eucalyptus sp.

Journal of Biotechnology and Biodiversity ◽

10.20873/jbb.uft.cemaf.v1n1.monteiro ◽

2010 ◽

Vol 1 (1) ◽

pp. 6-11

Author(s):

Thiago Campos Monteiro ◽

Renato da Silva Vieira ◽

José Tarcísio Lima ◽

Edy Eime Pereira Baraúna ◽

Duam Matosinhos de Carvalho ◽

...

Keyword(s):

Tension Wood ◽

Basic Density ◽

Eucalyptus Camaldulensis ◽

Normal Wood ◽

Reaction Wood ◽

Opposite Wood ◽

The Face ◽

Eucalyptus Maculata ◽

Shrinkage Coefficient

The reaction wood is formed in an attempt to remain upright tree in response to the action of forces such as winds, irregular crown or slope of the land that tend to incline it. In hardwoods, as in Eucalyptus, this type of wood is called tension wood and occurs in the region of the stem facing the face of force application. Indicative of the presence of this type of wood is the high shrinkage and basic density compared to normal wood. Once the basic density and shrinkage are parameters for determining the quality of the wood, this study aimed to evaluate the variation of basic density and shrinkage of opposite and tension wood along the radius in four species of Eucalyptus sp. Four tree species Eucalyptus camaldulensis, Eucalyptus maculata, Eucalyptus pilularis and Eucalyptus urophylla, with 32 years of age, were taken from an experimental planting of the Federal University of Lavras. Specimens were made to represent the diametrical variation of the opposite of tension wood in disks cut at the dbh. The results indicate that the properties of radial, tangential and volumetric shrinkage, coefficient of anisotropy and basic density did not differ statistically between the tensionand opposite wood.

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Viscoelastic properties of green wood across the grain measured by harmonic tests in the range 0–95°C: Hardwood vs. softwood and normal wood vs. reaction wood

Holzforschung ◽

10.1515/hf.2007.093 ◽

2007 ◽

Vol 61 (5) ◽

pp. 548-557 ◽

Cited By ~ 43

Author(s):

Vincent Placet ◽

Joëlle Passard ◽

Patrick Perré

Keyword(s):

Storage Modulus ◽

Viscoelastic Properties ◽

Tension Wood ◽

Radial Direction ◽

Lignin Content ◽

Softening Temperature ◽

Normal Wood ◽

Reaction Wood ◽

Opposite Wood ◽

Wood Compression

Abstract The viscoelastic properties of wood have been investigated with a dynamic mechanical analyser specifically developed for wooden materials, the WAVET device. Measurements were carried out on four wood species in the temperature range 0–100°C at frequencies varying between 5 mHz and 10 Hz. Wood samples were tested under water-saturated conditions in the radial and tangential directions. As expected, the radial direction always revealed a higher storage modulus than the tangential direction. Great differences were also observed in the loss factor. The tanδ peak and internal friction were higher in the tangential than in the radial direction. This behaviour is attributed to the fact that anatomical elements act as a function of the direction. The viscoelastic behaviour of reaction wood differs from that of normal or opposite wood. Compression wood of spruce, which has a higher lignin content, is denser and stiffer in transverse directions than normal wood, and has a lower softening temperature (T g). In tension wood, the G-layer is weakly attached to the rest of the wall layers. This may explain why the storage modulus and softening temperature of tension wood are lower than those for opposite wood. We also demonstrate that the time-temperature equivalence fits only around the transition region, i.e., between T g and T g+30°C. Apart from these regions, the response of wood reflects the combined effects of all its constitutive polymers, so that the equivalence is no longer valid.

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The nature of reaction wood. IV. Variations in cell wall organization of tension wood fibres

Australian Journal of Botany ◽

10.1071/bt9550177 ◽

1955 ◽

Vol 3 (2) ◽

pp. 177 ◽

Cited By ~ 53

Author(s):

AB Wardrop ◽

HE Dadswell

Keyword(s):

Cell Wall ◽

Tension Wood ◽

Secondary Wall ◽

Degree Of Crystallinity ◽

Tropical Species ◽

Normal Wood ◽

Reaction Wood ◽

Gelatinous Layer ◽

Wood Fibres ◽

Cell Wall Organization

The cell wall organization, the cell wall texture, and the degree of lignification of tension wood fibres have been investigated in a wide variety of temperate and tropical species. Following earlier work describing the cell wall structure of tension wood fibres, two additional types of cell wall organization have been observed. In one of these, the inner thick "gelatinous" layer which is typical of tension wood fibres exists in addition to the normal three-layered structure of the secondary wall; in the other only the outer layer of the secondary wall and the thick gelatinous layer are present. In all the tension wood examined the micellar orientation in the inner gelatinous layer has been shown to be nearly axial and the cellulose of this layer found to be in a highly crystalline state. A general argument is presented as to the meaning of differences in the degree, of crystallinity of cellulose. The high degree of crystallinity of cellulose in tension wood as compared with normal wood is attributed to a greater degree of lateral order in the crystalline regions of tension wood, whereas the paracrystalline phase is similar in both cases. The degree of lignification in tension wood fibres has been shown to be extremely variable. However, where the degree of tension wood development is marked as revealed by the thickness of the gelatinous layer the lack of lignification is also most marked. Severity of tension wood formation and lack of lignification have also been correlated with the incidence of irreversible collapse in tension wood. Such collapse can occur even when no whole fibres are present, e.g. in thin cross sections. Microscopic examination of collapsed samples of tension wood has led to the conclusion that the appearance of collapse in specimens containing tendon wood can often be attributed in part to excessive shrinkage associated with the development of fissures between cells, although true collapse does also occur. Possible explanations of the irreversible shrinkage and collapse of tension wood fibres are advanced.

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On the Chemistry of Tetrabenzyl Thiuram Disulfide and Tetramethyl Thiuram Disulfide with Bis (Triethoxysilylpropyl) Tetrasulfide in Silica Compounds

Rubber Chemistry and Technology ◽

10.5254/1.3547778 ◽

2003 ◽

Vol 76 (4) ◽

pp. 876-891 ◽

Cited By ~ 1

Author(s):

R. N. Datta ◽

A. G. Talma ◽

S. Datta ◽

P. G. J. Nieuwenhuis ◽

W. J. Nijenhuis ◽

...

Keyword(s):

High Performance ◽

Room Temperature ◽

Succinic Anhydride ◽

Dynamic Properties ◽

The Other ◽

Resonance Spectroscopy ◽

Reaction Products ◽

Negative Effect ◽

Higher Temperature ◽

Analytical Tools

Abstract The use of thiurams such as Tetramethyl thiuram disulfide (TMTD) or Tetrabenzyl thiuram disulfide (TBzTD) has been explored to achieve higher cure efficiency. The studies suggest that a clear difference exists between the effect of TMTD versus TBzTD. TMTD reacts with Bis (triethoxysilylpropyl) tetrasulfide (TESPT) and this reaction can take place even at room temperature. On the other hand, the reaction of TBzTD with TESPT is slow and takes place only at higher temperature. High Performance Liquid Chromatography (HPLC) with mass (MS) detection, Nuclear Magnetic Resonance Spectroscopy (NMR) and other analytical tools have been used to understand the differences between the reaction of TMTD and TESPT versus TBzTD and TESPT. The reaction products originating from these reactions are also identified. These studies indicate that unlike TMTD, TBzTD improves the cure efficiency allowing faster cure without significant effect on processing characteristics as well as dynamic properties. The loading of TESPT is reduced in a typical Green tire compound and the negative effect on viscosity is repaired by addition of anhydrides, such as succinic anhydride, maleic anhydride, etc.

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THE EFFECT OF SODIUM SILICATE AND ITS SOLUTION ON THE PROPERTIES OF REFRACTORY COMPLEX BINDER/NATRIO SILIKATO KIEKIO IR JO TIRPALO TANKIO ĮTAKA KOMPLEKSINIO KAITRAI ATSPARAUS RIŠIKLIO SAVYBĖMS

Journal of Civil Engineering and Management ◽

10.3846/13921525.1999.10531464 ◽

1999 ◽

Vol 5 (3) ◽

pp. 211-216

Author(s):

Valentin Antonovič ◽

Stasys Goberis ◽

Romualdas Mačiulaitis

Keyword(s):

Sodium Silicate ◽

Liquid Glass ◽

Solid Phase ◽

Physical And Mechanical Properties ◽

Alumina Cement ◽

Hardening Mechanism ◽

Temperature Range ◽

Calcium Hydrosilicates ◽

Higher Temperature ◽

Complex Binder

In order to improve thermal and mechanical characteristics of a traditional binder with liquid glass a complex binder consisting of liquid glass, its hardener and alumina cement (“Gorkal 70” containing not less than 70 per cent of AI2O3) was tested. Sodium silicate and its solution effect on physical and mechanical properties of a new refractory complex binder (Table 1, Fig 2) were investigated. The results obtained show that compressive strength of binding compound with high quantity of sodium silicate (N3) is the lowest after it had been cured, dried and fired at 300–600°C (Fig 3). It was also found that the strength of a complex binder with small quantity of sodium silicate (N1) in the temperature range of 20–600°C is 2–3 times as high as that of a traditional binder with dispersed fire-clay. The study in the formation of the structure of a complex binders dilatometric tests have also been made. After initial heating at 80–500°C the compositions contracted (Fig 4) due to dehidratation. At the temperature range of 580–750°C the contraction of compositions continue due to reactions at the solid phase. The hypothesis of the hardening mechanism in the complex binder was proposed. Liquid glass tends to restrain the hydration of the alumina cement though hardeners and sodium silicate interaction result in the intense formation of sodium calcium hydrosilicates. Therefore, a complex binder contains less sodium silicate than a traditional one while being used at higher temperature.

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Cross-field pitting characteristics of compression, lateral, and opposite wood in the stem wood of Ginkgo biloba and Pinus densiflora

IAWA Journal ◽

10.1163/22941932-00002107 ◽

2020 ◽

Vol 41 (1) ◽

pp. 48-60

Author(s):

Byantara Darsan Purusatama ◽

Nam Hun Kim

Keyword(s):

Electron Microscopy ◽

Scanning Electron Microscopy ◽

Ginkgo Biloba ◽

Compression Wood ◽

Pinus Densiflora ◽

Reaction Wood ◽

Stem Wood ◽

Opposite Wood ◽

The Cross ◽

Scanning Electron

Abstract The characteristics of cross-field pitting among compression wood, lateral wood, and opposite wood, in the stem woods of Ginkgo biloba and Pinus densiflora were investigated with optical and scanning electron microscopy. In Ginkgo biloba, compression wood exhibited piceoid pits, while lateral and opposite wood exhibited cupressoid pits. The compression wood of Pinus densiflora exhibited cupressoid pits and piceoid pits, while lateral wood and opposite wood exhibited pinoid and window-like pits in the cross-field. In both species, compression wood yielded the smallest pit number among each part, while opposite wood yielded the greatest pit number per cross-field. Cross-field pitting diameters of compression wood and opposite wood were significantly smaller than lateral wood in Ginkgo biloba, while the cross-field pitting of compression wood was the smallest in Pinus densiflora. Radial tracheid diameter of compression wood was slightly smaller than lateral and opposite wood in Ginkgo biloba and significantly smaller than lateral and opposite wood in Pinus densiflora. In conclusion, the cross-field pitting type, pit number, and cross-field pitting diameter could be used to identify reaction wood in the stem wood of Ginkgo biloba and Pinus densiflora.

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Effect of Temperature and Sisal Fiber Content on the Properties of Plaster of Paris

International Journal of Engineering & Technology ◽

10.14419/ijet.v7i4.20.25927 ◽

2018 ◽

Vol 7 (4.20) ◽

pp. 205 ◽

Cited By ~ 1

Author(s):

Aqil M. ALmusawi ◽

Thulfiqar S. Hussein ◽

Muhaned A. Shallal

Keyword(s):

Mechanical Properties ◽

Elevated Temperatures ◽

Physical And Mechanical Properties ◽

Fiber Content ◽

Sisal Fiber ◽

Effect Of Temperature ◽

Plaster Of Paris ◽

Micro Cracks ◽

Recent Developments ◽

Negative Effect

Recent developments in the production of ecologically friendly building composites have led to a renewed interest in the use of vegetable fibers as a reinforcement element. Traditional pure Plaster of Paris (POP) can suffer from the development of micro-cracks due to thermal expansion. Therefore, sisal fiber was studied for its potential as an ecological element to restrict and delay the development of micro-cracks in POP. Different sisal proportions of 0, 2, 4, 6, 8 and 10 wt. % of POP were used to characterize the physical and mechanical properties of POP at the ambient temperature. Then, the effects of temperatures of 25, 100, 200, 300, 400 and 500 were investigated. Results proved that the composite of 10% sisal fiber had the best mechanical properties. Also, when the fiber content was increased, the composite’s performance was enhanced, becoming better able to resist elevated temperatures. However, raising the temperature to 300 or above had a negative effect on the mechanical properties, which were significantly decreased due to the degradation of the sisal fiber.

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ANATOMY AND CHEMICAL COMPOSITION OF LIRIODENDRON TULIPIFERA STEMS INCLINED AT DIFFERENT ANGLES

IAWA Journal ◽

10.1163/22941932-00000078 ◽

2014 ◽

Vol 35 (4) ◽

pp. 463-475 ◽

Cited By ~ 3

Author(s):

Tokiko Hiraiwa ◽

Haruna Aiso ◽

Futoshi Ishiguri ◽

Yuya Takashima ◽

Kazuya Iizuka ◽

...

Keyword(s):

Lignin Content ◽

Fibre Length ◽

Liriodendron Tulipifera ◽

Original Position ◽

Chemical Characteristics ◽

Normal Wood ◽

Reaction Wood ◽

Glucose Content ◽

Wood Fibres ◽

S2 Layer

The anatomical and chemical characteristics of reaction wood (RW) were investigated in Liriodendron tulipifera Linn. Stems of seedlings were artificially inclined at angles of 30 (RW-30), 50 (RW-50) and 70° (RW-70) from the vertical, and compared with normal wood (NW) from a vertical seedling stem. The smallest values for the wood fibre length and vessel number were observed in RW-50. The pit aperture angle was less than 10° in RW-30 and RW-50, in which reduced lignin content was observed in the S2 layer of the wood fibres. An increase in the glucose content and a decrease in the lignin and xylose content was observed in RW-50. The stem inclination angle affected the degree of RW development with regard to anatomical and chemical characteristics: the severest RW was observed in RW-50, followed by RW-30. RW-70 was similar in anatomical and chemical characteristics to NW, apparently because the inclination was too strong to enable recovery of its original position. In this case a vertical sprouting stem was formed to replace the inclined stem.

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Strength and stiffness of the reaction wood in five Eucalyptus species

Holzforschung ◽

10.1515/hf-2018-0091 ◽

2019 ◽

Vol 73 (2) ◽

pp. 219-222

Author(s):

Bruno Charles Dias Soares ◽

José Tarcísio Lima ◽

Selma Lopes Goulart ◽

Claudineia Olímpia de Assis

Keyword(s):

Mechanical Behavior ◽

Tension Wood ◽

Compression Wood ◽

Vertical Position ◽

Eucalyptus Species ◽

Reaction Wood ◽

Opposite Wood ◽

Average Slope ◽

Strength And Stiffness

AbstractTree stems deviating from the vertical position react by the formation of tension wood (TW) or compression wood (CW), which are called in general as reaction wood (RW), in which the cells are modified chemically and anatomically. The focus of the present work is the mechanical behavior of TW in five 37-year-oldEucalyptusspecies, which were grown on a planting area with an average slope of 28% leading to decentralized pith in the trees, which is an unequivocal indication of the presence of RW. TW and opposite wood (OW) samples were isolated and subjected to a compression-parallel-to-grain test. It was observed that TW is less resistant and less stiff than the OW.

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