ABSTRACT
Thermally modified wood undergoes chemical, physical, and mechanical modifications, resulting in changes in resistance to wood biodegrading agents. The objective of this study was to evaluate the resistance to biodeterioration of thermally modified wood by the industrial process VAP HolzSysteme® of Eucalyptus grandis, Pinus taeda and Tectona grandis, submitted to the Lentinula edodes fungi (brown rot) and Pleurotus djamor fungi (white rot), and to analyze the chemical properties, contents of holocellulose, lignin, total extracts, and ash, before and after biodeterioration. Three treatments were considered for each species: Control - wood in natura, modified wood at 140 °C and 160 °C. The specimens were made according to ASTM D 1413 (ASTM, 1994), in a total of 108 samples per species, 36 per treatment for each species, with 12 samples submitted to the fungus L. edodes, 12 to P. djamor and 12 correction blocks. Different behaviors occurred among species under fungal action. For E. grandis wood the thermal modification increased the resistance to biodeterioration of the wood under the action of the L. edodes fungus, in the opposite way occurred for the species P. taeda. There was little variation between treatments in T. grandis wood for both fungi. Thermal modification conferred chemical alterations on the wood, influencing their behavior the biodeterioration by the fungal action in P. taeda species in a negative way, (increasing the degradation level), and E. grandis in a positive way, reducing the biodeterioration. However, in T. grandis species no significant differences were identified in the different treatments by the action of different rotting fungi.
Keywords: White rot; Brown rot; Rotting fungi; Thermal modification; Wood chemistry
INTRODUCTION
Brazil has more than 7.84 million hectares (MH) of planted forests. Among the genera planted, the highlights are Eucalyptus (5.67 MH), Pinus (1.58 MH), and Tectona (0.08 MH) (Ibá, 2019). The wood produced by such species is considered an alternative form of raw material, due to its economic and sustainable viability when compared to the use of native woods, as long as they have acceptable physical-mechanical and biological standards.
Resistance or natural durability is a parameter evaluated within the quality standards, which can be translated as the capacity of wood to resist the action of any agents that deteriorate the wood (Silva et al., 2005). Resistance to attacks by biological agents is due to the presence of extractives, which are toxic chemicals or repellents to xylophagous organisms. However, the distribution of extractives is different in each species, between trees and between portions of the wood. In general, the highest concentration of extractives is found in the heartwood and more precisely in the transition region to the sapwood, decreasing towards the medulla and increasing towards the stem base. This characteristic, together with the absence of nutritional material, ensures that the heartwood is the portion of the wood that represents greater natural durability (Silva et al., 2005; Paes et al., 2007).
The natural durability of Eucalyptus grandis Hill (ex Maiden) is moderate under the action of rotting fungi (IPT, 2013). The Pinus genus also presents a wood of moderate resistance when submitted to biodeterioration by fungi (Clausen, 2010), and the Tectona grandis L. f. wood has high natural durability and resistance to action of rotting fungi (IPT, 2013; Motta et al., 2013).
Among the rotting fungi, those ones causing white rot (because they cause characteristic white coloration in the wood) have the ability to degrade the lignin. The responsible ones for brown rot degrade hemicellulose and cellulose (holocellulose), and give the wood a darkened appearance (Gimenes, 2010; Moreschi, 2013).
The main rotting fungi belong to the Ascomycota (ascomycetes) and Basidiomycota (basidiomycetes) Divisions. Among the basidiomycetes, the species Lentinula edodes (Berk.) Pegler, edible fungus known worldwide as shiitake, is lignocellulite and classified as brown rot fungus (Santos, 2015). Fungi belonging to the Pleurotus genus are responsible for white rot, developing in tree trunks or dead wood, producing a white mycelium and degrading both lignin and cellulose (Menezes et al., 2017).
In order to improve the properties of wood, several techniques and treatments for preservation were developed. One of the procedures is thermal modification, used to change some technological characteristics of wood (physical-mechanical, chemical and biological), mainly dimensional stability, durability (Navi and Sandberg, 2012) and biological degradation resistance (Weiland and Guyonnet, 2003).
The chemical modifications in the cellular walls caused by thermal modification at certain temperatures, generally above 150 °C, are effective in altering the resistance of the wood to the attack of xylophagous agents (Boonstra et al., 2007). The durability of wood changes when thermally modified for two different reasons. The first one is the generation of new extractives during the process, which can act as a fungicide, and the second one is the increase in the hydrophobic characteristic of the wood, which reduces water absorption and hinders the development of fungi (Silva, 2012).
Due to these advantages, the main objective of this work was to evaluate the resistance to biodeterioration of thermally modified wood by the VAP HolzSysteme® process of the species E. grandis, Pinus taeda L. and T. grandis submitted to the L. edodes fungi and Pleurotus djamor fungi (Rumph. ex Fr.). Boedijn relating them to the fractions of chemical analysis.
MATERIAL AND METHODS
For each species, 60 pieces of 30 x 80 x 700 mm sawn wood were use, previously artificially dried at 10% humidity, divided into three lots containing 20 pieces per species. The first one that didn’t receive treatment, maintaining the properties of the wood in natura and the two other batches, were treated by the thermal modification process, called VAP HolzSysteme® at final process temperatures of 140 °C and 160 °C. The VAP HolzSysteme® process was carried out according to the methodology of the company TWBrazil, located in Ponta Grossa, Paraná (Batista, 2012).
Six pieces were randomly chosen from each species and modification temperature and, from these, six specimens of 19 x 19 x 19 mm were made according to the ASTM D 1413 standard (ASTM, 1994) in the Machining Laboratory of the Department of Forest Engineering and Technology (DETF) of the Universidade Federal do Paraná, Curitiba, Paraná. One hundred and eight specimens per species, 36 per temperature for each species (Figure 1), were prepared and stored in an incubator with forced air circulation at 103 °C until they reached a constant mass. After stabilization, the initial mass (M i ) was measured.
The prepared parts or specimens were submitted to an accelerated biodeterioration assay carried out at the Forest Pathology Laboratory from Embrapa Florestas, Colombo, Paraná. The specimens were subdivided into three treatments: Lentinula edodes and Pleurotus djamor fungi, causing brown and white rot, respectively, and control specimens, in each of these treatments 12 specimens were used (Figure 1). The fungi that were used in the biodeterioration test come from the fungi collection of the Non-Wood Products Laboratory from Embrapa Florestas, Colombo, Paraná.
The isolates were pricked from 0.5 cm diameter mycelium-agar discs, which were removed from the preservation vials and placed in disposable Petri dishes containing BDA (potato filter-agar) medium in a laminar flow hood, for growth of pure and active cultures of fungi and subsequent production of inoculum.
For the installation and conduct of the biodeterioration assay, 250 mL clear glass vials with wide mouth, metal screw cap with a 1 cm diameter hole containing 50 mL of BDA medium were used. The vials were sterilized with an autoclave at 121 °C and a pressure atmosphere for 20 minutes. The inoculation in the flasks occurred with the introduction of a 0.5 cm diameter agar-mycelium disk of the fungi L. edodes and P. djamor, for the respective species and modification temperatures. After the total growth of the fungi on the surface, the specimens of the species E. grandis, P. taeda and T. grandis were arranged in pairs, that is, two specimens for each vial, on the mycelial surface, and later the vials were capped. A cotton wick was placed in the hole of the caps to allow gas exchange. Additionally, six vials were prepared for treatment without inoculation of fungi, to serve as control. This control contained the 12 control specimens for each treatment in order to verify the loss of natural mass of the samples. After installation, the vials were incubated in a BOD chamber with a controlled temperature of 24 ± 2 °C and relative humidity of 70 ± 5 % for a period of eight weeks.
At the end of the incubation period, the specimens were placed in an oven at 103 °C. When reaching constant mass, the specimens were submitted to two stages of evaluation: the first stage to determine the final mass (M f ) and calculate the loss of mass (PM) in grams; and the second stage to determine the chemical properties of the wood under analysis. The calculation of mass loss (PM) was performed using Equation 1, where: PMcp - loss of weight of the specimen (%); Mi - initial mass (g); Mf - final mass (g). and Equation 2, where: PM - final mass loss (%); PMt - total mass loss of the specimen (%); PMbc - average mass loss of specimens without application of fungi (%).
The second stage of analysis was performed at the Wood Chemistry Laboratory from Universidade Federal do Paraná, Curitiba, Paraná, where the chemical properties of the wood were evaluated: content of extractives soluble in neutral organic solvents (ethanol:toluene at 1:2) according to TAPPI T204 cm (TAPPI, 1997); content of insoluble lignin according to TAPPI T222 om (TAPPI, 2002); ash content, TAPPI T211 om (TAPPI, 2002). The holocellulose content was obtained by difference according to Equation 3. To meet T257 cm-02 standard (TAPPI, 2002), the specimens were minced and ground in a knife mill and sieved in a set of 60 mesh and 40 mesh granulometry sieves. The particles retained in 40 mesh granulometry were used for chemical analysis. The specimens with fungi were cleaned with a hard bristle brush and a scalpel when necessary, removing the largest amount of mycelium. Six repetitions by factors were performed for non-biodeteriorated samples and three repetitions by factors for the other samples, due to the amount of material available after biodeterioration, using 30 grams of classified and dry sample. Equation 3, where: TLS - soluble lignin content (%); ET - total extractive content (%); C - ash content (%).
The statistical analysis was carried out in a completely randomized design, with a factorial arrangement, where the interactions between the following factors were analyzed: three species (E. grandis, P. taeda and T. grandis), with wood treatments (control - in natura and two heat treatments - 140 and 160 oC) and treatments with and without fungi (L. edodes and P. djamor). Six repetitions were used for biodegradation evaluations, and, for the chemical properties, three repetitions.
Bartlett’s test was used to verify the homogeneity of variances before performing the analysis of variance (ANOVA). The variances were homogeneous, requiring no data transformation. In cases where the null hypothesis was rejected in ANOVA, the Tukey test was used to differentiate the means. The level of significance adopted for all tests was p > 0.01.
RESULTS
The thermally modified wood of the tested forest species behaved differently to biodeterioration by fungi (Table 1).
The biodeterioration assay showed a difference in mass loss between the species studied. Figure 2 shows the biodeterioration process, with 30 and 60 days.
Biodeterioration test of thermally modified Tectona grandis wood with the fungus Lentinula edodes at 30 (a) and 60 days (b), and; Pinus taeda wood thermally modified with the fungus Pleurotus djamor at 30 (c) and 60 days (d).
The loss in mass of the species E. grandis presented a significant difference between the treatments for the L. edodes fungus with a tendency to reduce the loss in mass with the increase in temperature of the thermal treatments. There was a 34.5% and 47.5% reduction in biodegradation of the control for temperatures of 140 ºC and 160 ºC, respectively. Among the thermally modified woods, the reduction was 19.9 %. However, this reduction trend was not observed for the fungus P. djamor. A significant difference was observed only for the treatment at 140 ºC concerning the other treatments. Thus, treatment at 140 ºC can be considered the best treatment concerning the others, with a 43.2% reduction in mass loss when compared to the control.
Pinus taedawood showed an increase in mass loss of 50.4% and 253.8% at 140 ° C and 160 ° C respectively for the control. For the fungusP. djamor, the same behavior occurred, there was an increase in mass loss of 10.5% at 140 ºC and 179.0% at 160 ºC when compared to the control. The thermally modified wood ofPinus taedaproved to be more susceptible to biodegradable fungi.
Tectona grandis wood was the least biodegraded compared to other woods, 672.3 % and 89.9 % less compared to E. grandis and P. taeda of the wood in natura, respectively, submitted to the L. edodes fungus. A similar behavior was found for modified woods, at 140 ºC, where Tectona grandis biodeteriorated 200 % less than Eucalyptus and 69.3 % less than Pinus taeda, at 160 ºC, 192.1 % and 384.2 %, respectively. As for P. djamor fungus, there was no significant difference between Tectona grandis and Pinus taeda in the control treatment. However, among the Tectona grandis and Eucalyptus controls, there was a significant difference; the Eucalyptus wood was biodegraded 51.6% more than the Tectona grandis wood. At 140 ºC there was no significant difference in mass loss between species. At 160 ºC, Tectona grandis wood had the lowest loss in mass, 70.5% less than Eucalyptus and 153.3% less than Pinus. There was no significant difference between the temperatures of T. grandis wood, that is, the thermal modification did not influence the biodeterioration by the fungus P. djamor, and for L. edodes the thermal modification at 140 ºC provided a 68.61% greater degradation than the control, and at 160 ºC there was no significant difference in relation to the control.
It was observed that, as the wood modification temperature increased in the VAP HolzSysteme® process, the chemical properties of the wood changed (Tables 2, 3 and 4).
In non-biodegradable wood (without fungi), the holocellulose content in E. grandis, from the control sample for modified wood at 140 ºC, decreased significantly by 14.2%; this same trend was seen in Pinus with a reduction of 23.3%; and, in Tectona grandis wood, there was no significant reduction. For all species, there was a significant reduction in the holocellulose content between the control and the thermal modification 160 ºC, varying from 31.9%, 27.0%, and 24.0% for the respective species: E. grandis, P. taeda and T. grandis. The same behavior was observed between 140 ºC and 160 ºC, in Eucalyptus it decreased 20.6%, in Pinus, 4.8%, and in Tectona grandis, 23.4%.
The content of total extracts in non-biodegraded wood showed a significant difference between the control treatments, 140 ºC and 160 ºC, in all species analyzed, in E. grandis, P. taeda and T. grandis, from the control to 140 ºC they increased 186.76%, 219.78% and 14.13%, from the control to 160 ºC they increased 893.63%, 228.86% and 158.93% and from 140 ºC to 160 ºC increased 246.5%, 2.84% and 126.87%, respectively. In Pinus wood, there was no significant difference between treatments with thermal modification.
In non-biodeteriorated Pinus taeda woods, the lignin content increased significantly. From the control to 140 ºC, 9.19 %, from the control to 160 ºC, increased 16.52 % and from 140 ºC to 160 ºC, increased 6.71 %, noting a tendency to increase in the content of lignin with the increase in temperature of thermal modification.
T. grandis wood, without fungus, showed no significant difference in the lignin content between in natura and 140 ºC. However, there was a significant difference between in natura and at 160 ºC treatments, and 140 ºC and 160 ºC treatments, which increased the levels of lignin by 6.98% and 8.56%, respectively. For the E. grandis wood, there was also a significant difference between the treatments. From wood in natura to 140 ºC there was an increase of 24.99 %, from wood in natura to 160 ºC, it increased 17.97 %, and from 140 ºC to 160 ºC there was a reduction of 5.61 % in lignin content.
The ash content in the non-biodegraded wood had a different behavior between the coniferous ones and the hardwood ones. The ash content in Pinus increased by 142.86 % from control to 140 ºC, showed no difference between control and 160 ºC, and reduced from 140 ºC to 160 ºC by 56.86%. In the hardwood ones, the behavior was similar, from control to 140 ºC reduced 46.66% and 11.46%, Eucalyptus and Tectona grandis, respectively. From control to 160 ºC and from 140 ºC to 160ºC, the ash content in Eucalyptus increased 33.33% and 150%, and in Tectona grandis increased by 11.46% and 25.88%, respectively.
Observing the chemical properties of wood submitted to biodeterioration with the L. edodes fungi and P. djamor fungi in relation to wood without fungus, it was noted that the fungi consumed holocellulose significantly, of E. grandis and P. taeda.
The chemical analyses of thermally modified woods submitted to both fungi had different behaviors in relation to the control.
The fungi had preference in consuming the chemical compounds present in the total extractives of the thermally modified wood, with the exception of the E. grandis wood modified at 140 ºC, in which the L. edodes fungus consumed holocellulose (1.57 %) and lignin (1.54 %), but this consumption was not significant in relation to the material without fungus. There was significant consumption of holocellulose in wood modified at 140 °C of T. grandis, 4.82 % in relation to wood without fungus when submitted to L. edodes; and at 160 °C, 6.49 % when submitted to P. djamor fungus.
DISCUSSION
The chemical composition of each species results in different responses when subjected to thermal modification and resistance to biodeterioration (Boonstra et al., 2007). The resistance to biodeterioration of any wood is attributed to the presence of certain chemical compounds in the wood, such as tannins and other complex phenolic substances, toxic to biodeterioration agents (Paes, 2002). The natural durability of the wood depends on the degree of ease of access, to the interior of the wood, for the organisms to settle and the chemical composition. Fungal penetration pathways depend on: the structure and anatomical arrangements of the wood; the presence or absence of natural barriers (tyloses, punctuations, gums and resins); and chemical factors (cell wall polymers and extracts) (Eaton and Hale, 1993). The thermal modification altered the chemical composition of the analyzed wood, consequently altering the anatomical structure with respect to the constitution of the cell wall, providing more access routes for the penetration of fungi or not.
The increased susceptibility of P. taeda thermally modified wood to fungi attack can be attributed to changes in chemical compounds, certain complex phenolic substances that acted to repel the action of biodeterioration agents (Paes, 2002). It can also be attributed to anatomical (structural) changes suffered by the action of high temperature, providing greater penetration of fungi, reducing the natural durability of the wood. Brito et al. (2019) found similar results for the same type of thermally modified wood.
The thermal modification process provided E. grandis wood with greater resistance to biodeterioration by the fungus L. edodes at the two test temperatures, and by the fungus P. djamor, at 140 °C. The reduction in mass loss of the treated wood probably occurred due to changes in the chemical composition of the wood, producing new compounds that inhibit or repel the development of fungi. The increase in biodegradation by the white rot fungus, of wood modified at 160 °C in relation to thermal modification at 140 ° C, may have been caused by the alteration in the anatomical structure of the wood due to the increase in temperature, facilitating the penetration of the hyphae of the white rot fungus. Calonego et al. (2013), when performing biodeterioration by the brown rot fungus in thermally modified E. grandis, also found a reduction in mass loss with increasing temperature. In the field of decomposition, modified wood of the genus Eucalyptus showed little loss of mass compared to natural wood (Knapic et al. 2018).
Tectona grandis wood is naturally resistant to the action of xylophagous fungi. However, thermal modification increased the susceptibility of Tectona grandis wood, reducing the wood’s resistance to the attack of brown rot fungus, probably for the same reasons that increased the degradation in P. taeda wood, however to a lesser extent.
The E. grandis and T. grandis wood, in natura, were more deteriorated by the white rot fungus than the P. taeda wood. In general, white rot fungi deteriorate the angiosperm wood to a greater degree when compared to gymnosperm wood (Curling et al., 2000). In the present study, the fungus P. djamor, behaved in a manner contrary to that described by Curling et al. (2000) against thermally modified wood, deteriorating the wood of P. taeda (gymnosperm) to a greater degree. This is probably due to the chemical alteration suffered by the thermally modified wood, making the P. taeda wood more susceptible to action by the fungus P. djamor. The cleavage of hemicellulose into smaller molecular chains and the formation of new compounds facilitated the work of decomposing and transforming macromolecules into soluble compounds carried out by fungi to be assimilated and digested by them (Mendes and Alves, 1988).
Hemicellulose, a component of holocellulose, starts a strong degradation from a temperature close to 150 ºC (Sundqvist, 2004), that is, it is the first chemical component to be affected when the wood undergoes thermal modification processes, followed by cellulose and lignin degradation (Esteves et al., 2008; Brosse et al., 2010; Esteves, et al., 2013), which explains the reduction of the holocellulose content more effectively at the treatment temperature at 160 ºC in control. The reduction in holocellulose occurs due to the deacetylation of hemicellulose, attributed to the decomposition of the acetyl and acetoxy groups in xylan (Teejerdsma and Militz, 2005; Esteves et al., 2013). Yalcin and Sahin (2015), Batista et al. (2016), Lengowski et al. (2018), Pratiwi et al. (2019) observed a reduction in the content of holocelluloses after thermal modification in other species.
The increase in lignin content after the thermal modification process was also observed by Kamdem et al. (2002), Tjeerdsma and Militz (2005), Esteves et al. (2008), González-Peña et al. (2009), Brosse et al. (2010), Ding et al. (2011), Esteves et al. (2011), Moura et al. (2012) and Sikora et al. (2018). According to Esteves et al. (2013) and Cademartori et al. (2015), the increase in the percentage of lignin is due to the degradation of carbohydrates (hemicelluloses) and the formation of carbonyl groups in lignin (Li et al., 2002; Lopes et al., 2018).
The increase in total extractive content is due to the formation of new chemical compounds from the extraction of water and ethanol as a result of the degradation of polysaccharides (Rosa and Pereira, 1994; Esteves et al., 2008). This trend was found by Esteves et al. (2008), Brosse et al. (2010), Lengowski (2018), Batista (2012), Poubel et al. (2013) and Sikora et al. (2018). The new compounds were characterized by an increase in the total extractive content. In the biodeterioration process, the total extractive content of the modified wood was reduced, since the assimilation of the new compounds by the fungi occurred in all species and treatments.
CONCLUSIONS
The thermal modification caused chemical modifications in the wood, influencing the behavior of the species in the biodeterioration by the action of fungi.
The thermal modification at 140 ° C showed: a) the best temperature for the species Eucalyptus grandis concerning biodeterioration by fungi; b) the temperature provided in the lower increase in weight loss biodeterioration Pinus taeda on wood in nature, and; c) the temperature that gave less changes in the chemical structure of the species.
The process of thermal modification provided Pinus taeda wood with greater susceptibility to attack by the tested fungi.
Tectona grandis wood, independent of the thermal modification process, proved to be the most resistant to the attack of rotting fungi.
REFERENCES
- AMERICAN SOCIETY FOR TESTING AND MATERIALS (ASTM). ASTM D 1413: Standard Test Method for Wood Preservatives by Laboratory Soil-Block Cultures. West Conshohocken, 1994.
- BATISTA, D. C. Modificação térmica da madeira de Eucalyptus grandis em escala industrial pelo processo brasileiro VAP SystemeHolzSysteme® 2012. 339 f. PhD thesis Universidade Federal do Paraná, Curitiba.
- BATISTA, D. C., MUÑIZ, G. I. B. de, OLIVEIRA, J. T. da S., PAES, J. B., NISGOSKI, S. Effect of the Brazilian thermal modification process on the chemical composition of Eucalyptus grandis juvenile wood - Part 1: Cell wall polymers and extractives contents. Maderas. Ciencia y tecnología, v.18, n.2, p. 273 - 284, 2016.
- BRITO, J. O.; DIAS JÚNIOR, A. F.; LANA, A. Q.; ANDRADE, C. R.; BERNARDES, F. F. Biological resistance of heat-treated wood of Pinus caribaea and Eucalyptus saligna. Maderas. Ciencia y tecnología, v. 21, n. 2, p. 223 - 230, 2019.
- BROSSE, N.; HAGE, R. E.; CHAOUCH, M.; PÉTRISSANS, M.; DUMARCAY, S.; GÉRARDIN, P. Investigation of the chemical modifications of beech wood lignin during heat treatment. Polymer Degradation and Stability, v. 95, p.1721-1726, 2010.
- BOONSTRA, M. J.; ACKER, J. V.; KEGEL, E.; STEVENS, M. Optimisation of a two-stage heat treatment process: durability aspects. Wood Science and Technology, Berlin, v. 41, p. 41-57, 2007.
- CADEMARTORI, P. H. G. de; MISSIO, A. L.; MATTOS, B. D.; GATTO, D. A. Effect of thermal treatments on technological properties of wood from two Eucalyptus species. Anais da Academia Brasileira de Ciências, v.87, n.1, p. 471-481, 2015.
- CALONEGO, F. W.; ANDRADE, M. C. N. de; NEGRÃO, D. R.; ROCHA, C. D.; MINHONI, M. T. de A.; LATORRACA, J. V.; SEVERO, E. T. D. Behavior of the Brown-rot Fungus Gloeophyllum trabeum on Thermally-modified Eucalyptus grandis Wood. Floresta e Ambiente, Seropédica, v. 20, n. 3, p. 417-423, 2013.
- CLAUSEN, C. A.Biodeterioration of Wood. In: Wood handbook. General Technical Report FPL-GTR-190. Madison: U.S. Department of Agriculture, Forest Service, Forest Products Laboratory. 2010.
- CURLING, S.; WINANDY, J. E.; CLAUSEN, C. A. An experimental method to simulate incipient decay of wood by basidiomycete fungi. In: The International Research Group on Wood Preservation; Section 2, Test methodology and assessment; IRG/WP 00-20200, 31., 2000, Kona, USA. Proceedings, Kona: IRG, 13p. 2000.
- DING, T.; GU, L.; LIU, X. Influence of steam pressure on chemical changes of heat-treated mongolian pine wood. BioResources, v. 6, n.2, p. 1880-1889, 2011.
- EATON, R. A.; HALE, M. D. C. Wood: decay, pests and protection. Cambridge: Chapman & Hall. 541p. 1993.
- ESTEVES, B.; GRAÇA, J.; PEREIRA, H. Extractive composition and summative chemical analysis of thermally treated eucalypt wood. Holzforschung, v. 62, n.3, p.344-351, 2008.
- ESTEVES, B.; VIDEIRA, R. A.; PEREIRA, H. Chemistry and ecotoxicity of heat-treated pine wood extractives. Wood Sci Technol, v. 45, n. 6, p. 661-676, 2011.
- ESTEVES, B.; VELEZ MARQUES, A.; DOMINGOS, I.;PEREIRA, H. Chemical changes of heat-treated pine and eucalypt wood monitored by FTIR. Maderas, Ciencia y tecnología, v. 15, n.2, p. 245-258, 2013.
- GIMENES, L. J. Fungos Basidiomicetos: Técnicas de coleta, isolamento e subsídios para processos biotecnológicos. Instituto de Botânica de São Paulo, 2010.
- GONZÁLEZ-PEÑA, M. M.; CURLING, S. F.; HALE, M. D. C. On the effect of heat on the chemical composition and dimensions of thermally-modified wood. Polymer Degradation and Stability, v. 94, n. 12, p. 2184-2193, 2009.
-
INSTITUTO DE PESQUISAS TECNOLÓGICAS DE SÃO PAULO (IPT). 2013. Available at: <Available at: http://www.ipt.br/informacoes_madeiras/13.htm >. Accessed on: September 16, 2013.
» http://www.ipt.br/informacoes_madeiras/13.htm - KAMDEM, D. P. PIZZI, A.; JERMANNAUD, A. Durability of heat-treated wood. Holz als Roh- und Werkstoff, v. 60, n. 1, p. 1-6, 2002.
- KNAPIC, S.; SANTOS, J.; SANTOS, J.; PEREIRA, H. Natural durability assessment of thermo-modified young wood of Eucalyptus Maderas.Ciencia y tecnología, v. 20, n. 3, p.489 - 498, 2018.
- LENGOWSKI, E. C.; MUÑIZ, G. I. B. de; KLOCK, U.; NISGOSKI, S. Potential use of NIR and visible spectroscopy to analyze chemical properties of thermally treated wood. Maderas. Ciencia y tecnología, v.20, n.4, p. 627-640, 2018.
- LI, J.; LI, B.; ZHANG, X. Comparative studies of heat degradation between larch lignin and Manchurian ash lignin. Polymer Degradation and Stability, v. 78, p. 279-285, 2002.
- LOPES, J. de O.; GARCIA, R. A.; SOUZA, N. D. de. Infrared spectroscopy of the surface of thermally-modified teak juvenile wood. Maderas. Ciencia y tecnología, v. 20, n.4, p. 737 - 746, 2018.
- MENDES, A. de S.; ALVES, M. V. da S. A degradação da madeira e sua preservação. Brasília: IBDF, 57 p. 1988.
- MENEZES, F. P. BEVILACQUA, C. B.; SULZBACHER, M. A.; ANTONIOLLI, Z. I.; SEMINOTI, R. J. J. Capacidade dos fungos lignocelulolíticos em degradar polímeros de lodo de esgoto. Revista de Ciências Agrárias, Lisboa, v. 40, n. 3, p. 515-524, 2017.
- MODES, K. S. 2010. 99 f. Master dissertation Universidade Federal de Santa Maria, Santa Maria.
- MORESCHI, J. C. Biodegradação da Madeira. Biodegradação e Preservação da Madeira, 4ª edição, v.1. Universidade Federal do Paraná, abril/2013.
- MOTTA, J. P.; OLIVEIRA, J. T. S.; PAES, J. B.; ALVES, R. C.; DAMBROZ, G. B. V. Resistência natural da madeira de Tectona grandis em ensaio de laboratório. Ciência Rural, Santa Maria, v.43, n.8, p.1393-1398, ago, 2013.
- MOURA, L. F. de; BRITO, J.O.; SILVA JÚNIOR, F. G.da. Effect of thermal treatment on the chemical characteristics of wood from Eucalyptus grandis W. Hill ex Maiden under different atmospheric conditions. Cerne, v.18, n.3, p.449-455, 2012.
- NAVI, P.; SANDBERG, D. Thermo-hydro-mechanical wood processing. Boca Raton: CRC Press, 2012. 280 p.
- PAES, J. B. Resistência natural de madeira de Corymbia maculata (Hook.) K. D. HILL & L. A. S. Johnson a fungos e cupins xilófagos, em condições de laboratório. Revista Árvore, Viçosa (MG), v.26, n.6, p.761-767, 2002.
- PAES, J. B.; DE MELO, R. R.; DE LIMA, C. R. Resistência natural de sete madeiras a fungos e cupins xilófagos, em condições de laboratório. Cerne , v. 13, n. 2, p. 160-169, 2007.
- POUBEL, D. da S.; GARCIA, R. A.; SANTOS, W. A. dos; OLIVEIRA, G. de L.; ABREU, H. dos S. Efeito da termorretificação nas propriedades físicas e químicas da madeira de Pinus caribaea Cerne , v.19, n. 3, p.391-398, 2013.
- PRATIWI, L. A.; DARMAWAN, W.; PRIADI, T.; GEORGE, B.; MERLIN, A.; GÉRARDIN, C.; DUMARÇAY, S.; GÉRARDIN, P. Characterization of thermally modified short and long rotation teaks and the effects on coatings performance. Maderas. Ciencia y tecnología, v.21, n.2, p. 209-222, 2019.
-
RELATÓRIO ANUAL IBÁ . Indústria Brasileira de Árvores. Relatório Anual de 2016. Available at: Available at: http://iba.org/images/shared/Biblioteca/IBA_RelatorioAnual2016_.pdf Accessed on: July 16, 2019.
» http://iba.org/images/shared/Biblioteca/IBA_RelatorioAnual2016_.pdf - ROSA, E.; PEREIRA, H. The Effect of Long Term Treatment at 100 °C-150 °C on Structure, Chemical Composition and Compression Behaviour of Cork. Holzforschung , v. 48, n. 3, p. 226-232, 1994.
- SANTOS, L. F. de M. Potencial de deterioração de fungos apodrecedores de madeira em ensaios de laboratório. 2015. 47 f. Graduation of course work Universidade de Brasília, Brasília.
- SILVA, J. de C.; MATOS, J. L. M. de; OLIVEIRA, J. T. da S.; EVANGELISTA, W. V. Influência da idade e da posição ao longo do tronco na composição química da madeira de Eucalyptus grandis Hill ex. Maiden. Árvore, Viçosa, v. 29, n. 3, p. 455-460, 2005.
- SILVA, M. R. da. Efeito do tratamento térmico nas propriedades químicas, físicas e mecânicas em elementos estruturais de Eucalyptus citriodora e Pinus taeda 2012. 223f. PhD thesis Universidade de São Paulo, São Carlos.
- SIKORA, A.; KAČÍK, F.; GAFF, M.; VONDROVÁ, V.; BUBENÍKOVÁ, T.; KUBOVSKÝ, I. Impact of thermal modification on color and chemical changes of spruce and oak wood. Journal of Wood Science, v.64, p. 406-416, 2018.
- SUNDQVIST, B. Colour changes and acid formation in wood during heating. 2004. 154 f. PhD thesis Luleå University of Technology, Skellefteå.
- TECHNICAL ASSOCIATION OF PULP AND PAPER INDUSTRY (TAPPI) . T204 cm: Solvent extractives of wood and pulp. Norcross, 1997.
- TECHNICAL ASSOCIATION OF PULP AND PAPER INDUSTRY (TAPPI) . T211 om: Ash in wood, pulp, paper and paperboard: combustion at 525°C. Norcross, 2002.
- TECHNICAL ASSOCIATION OF PULP AND PAPER INDUSTRY (TAPPI). T222 om: Acid insoluble lignin in wood and paper. Norcross, 2002.
- TECHNICAL ASSOCIATION OF PULP AND PAPER INDUSTRY (TAPPI). T257 cm-02: Sampling and preparing wood for analysis. Norcross, 2002.
- TJEERDSMA, B.; MILITZ, H. Chemical changes in hydrothermal treated wood: FTIR analysis of combined hydrothermal and dry heat-treated wood. Holz als Roh und Werkst, v.63, n. 2, p. 102-111, 2005.
- WEILAND, J.; GUYONNET, R. Study of chemical modifications and fungi degradation of thermally modified wood using DRIFT spectroscopy. Holz als Roh und Werkstoff, Germany, v.61, p.216-220, 2003.
- YALCIN, M.; SAHIN, H. I. Changes in the chemical structure and decay resistance of heat-treated narrow-leaved ash wood. Maderas. Ciencia y tecnología. v. 17, n. 2, p. 435 - 446, 2015.
HIGHLIGHTS:
-
1
The increase in total extractive content is a result of polysaccharide degradation.
-
2
There is an increase in lignin content after the thermal modification process.
-
3
The chemical changes in wood influence the biodeterioration by fungi.
-
4
The thermally modified wood behaved differently to biodeterioration by fungi.
Publication Dates
-
Publication in this collection
16 Dec 2020 -
Date of issue
Jul-Sep 2020
History
-
Received
27 Jan 2020 -
Accepted
05 Aug 2020