Your search keyword '"Christian Brischke"' showing total 162 results

1. Biological resistance of thermally modified Gmelina arborea wood

Author

Maxidite Minkah, Kojo Agyapong Afrifah, Charles Antwi-Boasiako, Ana Paula Soares da Silva, Jaqueline Rocha de Medeiros, Juarez Paes, Cesar Vicente Ferreira Batista, Christian Brischke, and Holger Militz

Subjects

Coniophora puteana, Cryptotermes brevis, decay resistance, Macrotermes spp., durability, fungi, Forestry, SD1-669.5, Manufactures, TS1-2301

Abstract

Thermal modification of wood is an environmentally friendly method to improve wood durability, mainly against microorganisms. By employing a process similar to the ThermoWood®, various Gmelina arborea (gamhar) wood specimens were thermally modified at 180 °C, 200 °C, and 220 °C for 3 hours. The effects of the thermal modification process on the resistance to decay by rot-fungi, and attack by subterranean, arboreal, and dry-wood termites were determined. Generally, the thermal modification improved the resistance of Gmelina arborea (gamhar) to decay by Trametes versicolor with increasing process temperature. However, the effect of the process was null on the resistance to biodeterioration by the brown-rot fungus Coniophora puteana and the dry-wood termites Cryptotermes brevis. Even so, the visual damage caused by Cryptotermes brevis was slight. Untreated and thermally modified woods recorded higher resistance to Coniophora puteana than Trametes versicolor. Mass loss caused by Nasutitermes corniger also decreased with increasing thermal modification temperature. According to the visual damage rating values, the attack by Nasutitermes corniger was slight. However, the thermal modification inversely impacted Gmelina arborea (gamhar) attack by Macrotermes sp., as its resistance in the field to the termites decreased with increasing modification temperature. Thus, the thermal modification process contributed to improving the decay resistance of the modified wood to white-rot fungus Trametes versicolor and attack by the arboreal termites Nasutitermes corniger exposed indoors. On the other hand, thermally modified Gmelina arborea (gamhar) wood was very susceptible to Macrotermes sp. in the field. This work would provide a reliable reference document to guide wood industry stakeholders in assessing the performance of untreated and thermally modified Gmelina arborea (gamhar) wood in situations exposed to fungi and termite species adopted.

Published

2024

2. Statistical Analysis of Wood Durability Data and Its Effect on a Standardised Classification Scheme

Author

Christian Brischke, Felix Haase, Lea Bächle, and Susanne Bollmus

Subjects

EN 113-2, EN 350, fungal decay, probability density function, wood mass loss, wood durability classes, Mathematics, QA1-939, Applied mathematics. Quantitative methods, T57-57.97

Abstract

The biological durability of wood is an important property for outdoor applications of wood-based products. In temperate climate zones, the most critical biological hazard is wood-destroying fungi, and the European standard EN 350 in combination with EN 113-2 provide guidance on sampling, testing, and classifying wood durability against brown and white rot fungi. However, in their latest revised versions, both standards recommend the use of probability density functions for fitting mass loss data (ML). Subsequently, the durability of wood and its variability should be further characterised. The aim of this study was to statistically analyse the ML data from laboratory agar plate tests with different European-grown wood species and to examine the effect of different statistical treatments on the standardised classification scheme of wood durability. It was concluded that more precise guidance is needed on the sampling procedure since significant differences in durability exist between stem zones. The assignment of dispersion indicators requires a revision to ensure clear, unmistakable, and reproducible durability classification of wood. Deficits in the description of the proposed statistical treatments in both standards became evident. It can be questioned whether the application of probability density functions provides additional information about the variability of wood durability.

Published

2023

3. Modelling in-ground wood decay using time-series retrievals from the 5th European climate reanalysis (ERA5-Land)

Author

Brendan N. Marais, Marian Schönauer, Philip Bester van Niekerk, Jonas Niklewski, and Christian Brischke

Subjects

Fungal wood decay, dose–response model, IRG-WP durability database, geospatial modelling, soil moisture, soil temperature, Oceanography, GC1-1581, Geology, QE1-996.5

Abstract

ABSTRACTThis article presents models to predict the time until mechanical failure of in-ground wooden test specimens resulting from fungal decay. Historical records of decay ratings were modelled by remotely sensed data from ERA5-Land. In total, 2,570 test specimens of 16 different wood species were exposed at 21 different test sites, representing three continents and climatic conditions from sub-polar to tropical, spanning a period from 1980 until 2022. To obtain specimen decay ratings over their exposure time, inspections were conducted in mostly annual and sometimes bi-annual intervals. For each specimen’s exposure period, a laboratory developed dose–response model was populated using remotely sensed soil moisture and temperature data retrieved from ERA5-Land. Wood specimens were grouped according to natural durability rankings to reduce the variability of in-ground wood decay rate between wood species. Non-linear, sigmoid-shaped models were then constructed to describe wood decay progression as a function of daily accumulated exposure to soil moisture and temperature conditions (dose). Dose, a mechanistic weighting of daily exposure conditions over time, generally performed better than exposure time alone as a predictor of in-ground wood decay progression. The open-access availability of remotely sensed soil-state data in combination with wood specimen data proved promising for in-ground wood decay predictions.

Published

2023

4. Impact of Wood Moisture Content on Structural Integrity of Wood Under Dynamic Loads

Author

Lukas Emmerich and Christian Brischke

Subjects

brittleness, high-energy multiple impact (hemi) test, moisture content, moisture states, resistance to impact milling (rim), Forestry, SD1-669.5

Abstract

The majority of mechanical wood properties are negatively affected by wood moisture within the hygroscopic range, disregarding the stress relaxation of wood at very low moisture contents (MC). In contrast, the structural integrity and thus the brittleness of wood appears to be positively affected by moisture. This study aimed at examining the effect of wood MC on the structural integrity of wood between the oven-dry state and MC well above cell wall saturation (CWS), i.e., at approx. 100 %. For both softwood (Picea abies) and hardwoods (Fagus sylvatica and Quercus robur), the structural integrity was assessed on the basis of the Resistance to Impact Milling (RIM) originating from High-Energy Multiple Impact (HEMI) tests. RIM increased with increasing MC in the hygroscopic range, which might be explained by stress relaxation and ‘gluing effects’ inside the cell wall polymer structure, resulting from a growing network of hydrogen bonds on cell wall level. Increasing MC above CWS caused a slight decrease of RIM in the selected hardwood species, whereas no significant change in RIM was observed when MC varied in the range from CWS to approx. 100 % for the softwood species Norway spruce.

Published

2023

5. Incising and Double Impregnation of Beech Sleepers—Investigation of an Alternative Preservation System for Wooden Railway Sleepers

Author

Michael Starck, Andreas Heidel, Christian Brischke, and Holger Militz

Subjects

creosote, incising, moisture content monitoring, oily preservative, railway sleepers, ties, Forestry, SD1-669.5, Environmental sciences, GE1-350

Abstract

For nearly 200 years wooden railway sleepers are impregnated with creosote. After initially using vacuum pressure processes for impregnation, empty-cell processes have been developed quickly and are used until today. Because of political developments and its alarming properties against human health and environment the use of creosote is already restricted to certain industrial and commercially used products and will probably be banned on the European market and elsewhere in the near future. Today, most of the sleepers in track are concrete sleepers, but wooden sleepers are still essential for particular applications such as tracks with narrow curve radii, mountain tracks with uneven underground conditions and low ballast bed thicknesses, for switches, for railway bridges and for shunting stations. Without a successor product, wooden sleepers have to be installed either again without adequate protection against wood destroying organisms or will possibly be replaced by sleepers made from alternative materials like concrete, steel or polymers. The Fürstenberg-System-Sleeper, which combines a mechanical pre-treatment (incising), a double impregnation of sleepers including an alternative oily wood preservative and a water-borne copper salt as well as a modernized quality control shall on the one hand serve as an alternative to creosoted sleepers and on the other hand ensure future use of wooden sleepers in track superstructure. Incising reduced the formation of checks regarding their length, width, and depth in sleepers made from European beech (Fagus sylvatica L.) until they are sufficiently seasoned for impregnation. A decrease of the seasoning speed was not observed. During seasoning, the average global moisture content (MC) as well as the local MC showed hardly any differences between incised and not incised sleepers. Additionally, incising showed no influence on the dimensional stability, which would have reduced the number of sleepers being culled based on excessive deformation. Furthermore, positive effects on preservative retention and penetration were observed, where incising doubled the penetration depth up to over 30 mm and increased the mean retention from 46.5 to 72.0 kg/m3. During double impregnation with the water-borne preservative first and the oily preservative afterward, it became evident, that a gross weight of at least 950 kg/m3 was needed for penetrating the peripheral area of the sleepers to achieve an additional homogenous envelope treatment during the second impregnation with an average retention of approximately 30 kg/m3.

Published

2022

6. Decadal Variations of Wood Decay Hazard and El Niño Southern Oscillation Phases in Iran

Author

Jalil Helali, Hossein Momenzadeh, Vahideh Saeidi, Christian Brischke, Ghanbar Ebrahimi, and Mohammad Lotfi

Subjects

Scheffer Climate Index, wood decay hazard, wood decay risk, ENSO (El Niño Southern Oscillation), Mann–Kendall (MK), Forestry, SD1-669.5, Environmental sciences, GE1-350

Abstract

The intensive use of wood resources is a challenging subject around the world due to urbanization, population growth, and the biodegradability of wooden materials. The study of the climatic conditions and their effects on biotic wood degradation can provide a track of trends of wood decay and decomposition at regional and global scales to predict the upcoming responses. Thus, it yields an overview for decision-makers and managers to create a precise guideline for the protection of wooden structures and prolonged service life of wooden products. This study aimed at investigating the decay hazard in Iran, its decadal changes, and how it is affected by different phases of the El Niño Southern Oscillation (ENSO). Therefore, the risk for fungal decay of wood was estimated based on the Scheffer Climate Index (SCI) at 100 meteorological stations located in Iran, for the period 1987–2019 (separately for first, second, and third decade as decadal analysis). Subsequently, SCI value trends were analyzed using the Mann–Kendall and Sen’s slope method. Finally, the relationship between SCI and climatic parameters (temperature and precipitation) was explored. Generally, the SCI fluctuated between 2 and 75 across the region. The decay risk was ranked as low in most parts, but moderate in the northern part of the country along the Caspian Sea coastlines. Decadal analysis demonstrated that the highest mean SCI values took more place in the third decade (58% of stations) and the lowest mean SCI values in the second decade (71% of stations). Furthermore, the highest and the lowest SCI values occurred at 70 and 66% of stations in El Niño and Neutral phase, respectively. Trend analysis of SCI values showed that large parts of several provinces (i.e., Markazi, Tehran, Alborz, Qazvin, Zanjan, Ardebil, East Azarbayjan, West Azarbayjan, Kurdestan, Kermanshah, and Ilam) exhibited a significantly increasing decay hazard with a mean SCI of 2.9 during the period of 33 years. An analysis of causative factors (climatic parameters) for these changes revealed that all the meteorological stations experienced a significant increase in temperature while the number of days with more than 0.25 mm precipitation increased at some stations but decreased at others. However, in summary, the SCI increased over time. Hence, in this study, the effect of precipitation on SCI was confirmed to be greater than the temperature. Analysis of the results shows that the correlation between the SCI and ENSO was positive in most of the stations. Moreover, the results of spectral coherent analysis of SCI and ENSO in different climates of Iran showed that the maximum values of SCI do not correspond to the maximum values of ENSO and are associated with lag time. Therefore, the extreme values of the SCI values cannot be interpreted solely on the basis of the ENSO.

Published

2021

7. Durability of Wood in Ground Contact – Effects of Specimen Size

Author

Christian BRISCHKE and Linda MEYER-VELTRUP

Subjects

decay, dimension, durability testing, in ground exposure, soil contact, Forestry, SD1-669.5

Abstract

The durability of wood in ground contact is affected by its material resistance on the one hand, and the exposure situation in the ground on the other hand. The latter is considered to be one of the most severe not at least due to permanent wetting and direct contact to a well-established microbial flora. In addition to physical, chemical, biological, and ecological soil parameters, the design of a wooden commodity which is in contact with the ground can have an effect on its durability. This study examined the effect of size of specimens used for in-ground durability tests. Standard EN 252 specimens, smaller mini-stake specimens, and larger double-size specimens were made from Scots pine sapwood and heartwood (Pinus sylvestris L.), Norway spruce (Picea abies Karst.), beech (Fagus sylvatica L.), and English oak (Quercus robur L.) and exposed in ground in a test field in Hannover-Herrenhausen, Germany. In addition, standard size specimens were exposed on the ground. Decay rates and corresponding durability classes according to European standards were determined. Decay proceeded slightly faster with decreasing specimen size, but for the majority of the tested materials no significant effect became apparent. However, the most durable material tested was English oak, for which durability was clearly affected by the specimen size. It was classified ‚durable’ (durability class DC 2) using double size stakes, ‚moderately durable’ (DC 3) using standard specimens, and ‚less durable’ (DC 4) using mini-stake specimens. Specimens exposed on-ground decayed significantly less rapidly compared to specimens buried in the ground to half of their length. The findings from this study recommend to use also test specimens, which are bigger dimensioned than standard specimens and thus closer in dimension to real size commodities. Otherwise, one might accept to underestimate the durability of particular wood-based materials.

Published

2017

8. Dynamic and static mechanical properties of eucalyptus nitens thermally modified in an open and closed reactor system

Author

Maximilian Wentzel, Christian Brischke, and Holger Militz

Subjects

Bending, deflection, high energy multiple impact test, modulus of elasticity, modulus of rupture, wood anatomy, Forestry, SD1-669.5, Manufactures, TS1-2301

Abstract

Eucalyptus nitens is a fast growing plantation species that has a good acclimation in Chile. It is commonly used for pulp and paper, but there is a growing market for solid wood products made from this species and an interest on producing high quality material. Thermal modification technology have been used to obtain high quality product out of fast growing plantation species. In this study we modified Eucalyptus nitens to analyse the influences of the process conditions and evaluated its mechanical properties under several process conditions. The material was modified in a closed system under elevated pressure and controlled relative humidity (30 and 100% relative humidity) at temperatures between 150 and 170°C, and in an open system with a standard thermal modification procedure between 160 and 230°C. Modulus of elasticity, modulus of rupture, deflection and work in bending (in elastic and inelastic proportions) and the resistance to impact milling in high energy multiple impact tests were determined. Mass loss after each modification was also measured and correlated with the mechanical properties. Anatomical properties of selected modifications were analysed. There were no significant differences between open and closed system modifications in both mechanical and anatomical properties.

Published

2019

9. Resistance of Injection Molded Wood-Polypropylene Composites against Basidiomycetes According to EN 15534-1: New Insights on the Test Procedure, Structural Alterations, and Impact of Wood Source

Author

Kim Christian Krause, Christian Brischke, Tim Koddenberg, Andreas Buschalsky, Holger Militz, and Andreas Krause

Subjects

wood–polypropylene composites, wpc, en 15534-1, durability test, basidiomycetes, wood–moisture interaction, mechanical properties, x-ray micro-computed tomography, Chemicals: Manufacture, use, etc., TP200-248, Textile bleaching, dyeing, printing, etc., TP890-933, Biology (General), QH301-705.5, Physics, QC1-999

Abstract

In this study, we investigated injection molded wood-polypropylene composites based on various wood sources and their decay resistance against white rot (Trametes versicolor) and brown rot (Coniophora puteana) in a laboratory test according to EN 15534-1:2014. The manufactured composites consisted of poplar (Populus spp.), willow (Salix spp.), European beech (Fagus sylvatica L.), Norway spruce (Picea abies (L.) H. Karst.), and a commercial wood source (Arbocel® C100), respectively. All formulations were compounded on a co-rotating twin screw extruder and subsequently injection molded to wood−PP specimens with a wood content of 60% or 70% by weight. It was found that the test procedure had a significant effect on the mechanical properties. Loss in mechanical properties was primarily caused by moisture and less by fungal decay. Moisture caused a loss in the modulus of rupture and modulus of elasticity of 34 to 45% and 29 to 73%, respectively. Mean mass and wood mass losses were up to a maximum of 3.7% and 5.3%, respectively. The high resistance against fungal decay was generally attributed to the encapsulation of wood by the polymer matrix caused by sample preparation, and enhanced by reduced moisture uptake during the preconditioning procedure. Notable differences with respect to the wood particle source and decay fungi were also observed. Structural characterization confirmed the decay pattern of the fungi such as void cavities close the surface and the deposition of calcium oxalates.

Published

2019

10. Natural Durability of Timber Exposed Above Ground – a Survey

Author

Christian Brischke, Linda Meyer, Gry Alfredsen, Miha Humar, Lesley Francis, Per-Otto Flæte, and Pia Larsson-Brelid

Subjects

durability classes, field tests, resistance factor, service life prediction, test methodology, use class 3, Forestry, SD1-669.5

Abstract

Besides its inherent resistance against degrading organisms, the durability of timber is influenced by design details and climatic conditions, making it difficult to treat wood durability as an absolute value. Durability classification is, therefore, based on comparing performance indicators between the timber in question and a reference timber. These relative values are grouped and related to durability classes, which can refer to a high range of service-lives. The insufficient comparability of such durability records has turned out to be a key challenge for service-life prediction. This paper reviewed literature data, based on service-life measures, not masked by a durability classification. It focused on natural durability of timber tested in the field above-ground. Additionally, results from ongoing aboveground durability studies in Europe and Australia are presented and have been used for further analysis. In total, 163 durability recordings from 31 different test sites worldwide based on ten different test methods have been considered for calculation of resistance factors. The datasets were heterogeneous in quality and quantity; the resulting resistance factors suffered from high variation. In conclusion, an open platform for scientific exchange is needed to increase the amount of available service-life related data.

Published

2013

11. Performance of thermally modified timber (TMT) in outdoor application – durability, abrasion and optical appearance

Author

Christian R. Welzbacher, Christian Brischke, Andreas O. Rapp, Silvia Koch, and Sabine Hofer

Subjects

blue stain, cracks, decking, façade, weathering, Forestry, SD1-669.5

Abstract

Thermally modified timber (TMT) is increasingly offered in Europe as an alternative to preservative treated timber. TMT durability in field tests as well as its moisture sorption behaviour in façade application was determined so as to consider its suitability for outdoor use. Additionally, abrasion and crack-formation of TMT deckings were examined and the optical appearance of a TMT façade was evaluated after 5 years of service. After 7.5 years exposure in ground contact, the various TMT materials tested were classed as “slightly durable” to “not durable” whereas the classification in above ground exposure as “very durable” to “moderately durable”, which was in line with the reduced moisture sorption of TMT in weathered application. Moreover, the TMT-decking showed less abrasion and crack-formation compared to references, though the TMT façade revealed considerable discoloration by weathering. Hence, the suitability of TMT for above ground use is suggested, but a surface treatment is obligatory if discoloration is objectionable.

Published

2009

12. Biological durability and moisture dynamics of Dawn redwood (Metasequoia glyptostroboides) and Port Orford cedar (Chamaecyparis lawsoniana)

Author

Christian Brischke, Susanne Bollmus, Eckhard Melcher, and Ina Stephan

Subjects

General Materials Science

Published

2022

13. Statistical Analysis of Wood Durability Data and Its Effect on a Standardised Classification Scheme

Author

Bollmus, Christian Brischke, Felix Haase, Lea Bächle, and Susanne

Subjects

EN 113-2, EN 350, fungal decay, probability density function, wood mass loss, wood durability classes, wood-based products

Abstract

The biological durability of wood is an important property for outdoor applications of wood-based products. In temperate climate zones, the most critical biological hazard is wood-destroying fungi, and the European standard EN 350 in combination with EN 113-2 provide guidance on sampling, testing, and classifying wood durability against brown and white rot fungi. However, in their latest revised versions, both standards recommend the use of probability density functions for fitting mass loss data (ML). Subsequently, the durability of wood and its variability should be further characterised. The aim of this study was to statistically analyse the ML data from laboratory agar plate tests with different European-grown wood species and to examine the effect of different statistical treatments on the standardised classification scheme of wood durability. It was concluded that more precise guidance is needed on the sampling procedure since significant differences in durability exist between stem zones. The assignment of dispersion indicators requires a revision to ensure clear, unmistakable, and reproducible durability classification of wood. Deficits in the description of the proposed statistical treatments in both standards became evident. It can be questioned whether the application of probability density functions provides additional information about the variability of wood durability.

Published

2023

14. Laboratory Durability Testing of Preservative-Treated Wood Products

Author

Christian Brischke, Marten Sievert, Max Schilling, and Susanne Bollmus

Subjects

commodity testing, decay test, durability classification, EN 350, preservative-treated wood, Forestry

Abstract

Recently, certain European standards have allowed for the classification of the biological durability of chemically modified wood and preservative-treated wood, including treated products, but necessary methods for representative sampling and testing are lacking. Instead of sampling from products that can contain areas of varying durability, this study aimed at testing full-size products. Sections of untreated and preservative-treated terrace decking and palisades were incubated with pure cultures of brown and white rot fungi. Instead of mass loss, the decayed cross-sectional area was determined. The spatial distribution of decay and wood moisture content was investigated. After 16 weeks of incubation, all untreated product specimens showed signs of decay independent of the test fungus. The treated specimens were less affected. The mean and the maximum decayed cross-sectional areas were well correlated, for both the total and the sapwood cross-sections. The wood moisture content after incubation was always favorable for fungal decay, but highest where the specimens were in direct contact with the malt agar. Different infestation pathways became evident: (1) from the sapwood mantle, (2) via radial checks, and (3) from the end-grain. The latter should be prevented in order to better mimic real outdoor exposure conditions.

Published

2023

15. The durability of acetylated beech (Fagus sylvatica L.) laminated veneer lumber (LVL) against wood-destroying basidiomycetes

Author

Maik Slabohm, Christian Brischke, and Holger Militz

Subjects

General Materials Science, Forestry

Abstract

The overall aim of this study was to investigate the durability of acetylated beech (Fagus sylvatica L.) laminated veneer lumber (LVL) against wood-destroying basidiomycetes. The secondary objective was to test whether the specimen size affects the mass loss and durability assessment of wood-material under test. The durability test was based on the pre-standard prEN 113-3. Six materials (acetylated beech LVL, untreated beech LVL, beech solid wood, pine sapwood (Pinus sylvestris L.), larch (Larix decidua Mill.) 3-layer slab, larch solid wood) were tested using three specimen geometry designs (50 × 25 × 15 mm3 as well as 50 × 50 × 19 mm3 with and without sealed edges) against Coniophora puteana, Rhodonia placenta, Gloeophyllum trabeum, Trametes versicolor, and Pleurotus ostreatus. The durability assessment was made using the arithmetic mean and median percentage mass loss (ML), the relative ML (x-values), and the decay susceptibility index (DSI). It was found that mass loss was affected by the test fungus, the material, and the specimen size and design, with the latter being the most essential factor in this study. In addition, the assessment parameter had a significant effect on the durability classification. Furthermore, small differences in ML resulted in different durability classes (DC) in some cases, whereas large differences in ML did not. However, acetylated beech LVL was always considerably durable (DC 1) against all tested fungi independent of the specimen design and durability assessment method.

Published

2023

16. Properties of Mexican bloodwood (Haematoxylum campechianum L.). Part 1: anatomical and colourimetric characteristics

Author

Tim Koddenberg, Christian Brischke, Lukas Emmerich, and Annika B. E. Kick

Subjects

Biomaterials

Abstract

Bloodwood (Haematoxylum campechianum L.) native to Central America has been known as dye source since the prehistoric times by the Maya. Nowadays, bloodwood is increasingly used for plantations but its use for furniture, flooring, or fencing is only of regional importance. The reason is seen in lacking knowledge of its properties. To expand that knowledge, this Part 1 of the two-part study series investigated the anatomy and the discolouration due to leaching of heartwood of H. campechianum. Anatomical characteristics were described qualitatively and quantitively using scanning electron microscopy and X-ray micro-computed tomography. Detailed wood anatomical data are presented, together with numerical analyses of cell parameters. Apart from wood anatomy, colourimetric analyses were obtained after 10 leaching cycles. The colour change of the wood due to water exposure was determined measuring in CIE L*a*b* colour system. In addition, the extinction of the leachate was determined spectrophotometrically after each leaching cycle. The resulting colour change was evaluated according to colour change after each cycle. The most prominent change in colour was observed for the first cycle due to leaching. Because of the extensive leaching of extractives, further investigation might address the effect of leaching of water-soluble extractives on adhesion properties of bloodwood.

Published

2022

17. Properties of Mexican bloodwood (Haematoxylum campechianum L.). Part 2: moisture performance and biological durability

Author

Christian Brischke, Lukas Emmerich, Tim Koddenberg, and Annika E. B. Kick

Subjects

Biomaterials

Abstract

Haematoxylum campechianum is most prevalently used as dyewood; its use for furniture, flooring, or fencing is only of regional importance, which might be due to lacking data about its technological properties. Therefore, small specimens were cut from H. campechianum stems from plantations in the lowlands of the Usumacinta delta in Mexico. The latter were subjected to laboratory decay and moisture studies. Water vapour sorption, liquid water uptake, and swelling of H. campechianum appeared much lower in comparison with most European grown wood species and similar to tropical hardwoods such as Tectona grandis. After removal of water-soluble ingredients, water vapour sorption of H. campechianum specimens further decreased, which assigned such ingredients a somewhat hydrophilic character. Mean mass losses (ML) due to decay by white, brown, and soft rot fungi in laboratory tests were T. grandis and Intsia bijuga. Based on this preliminary property profile, H. campechianum can be recommended for both outdoor (e.g. fencing, outdoor decking, railing) and indoor applications (e.g. flooring, manufacturing of furniture, wall and ceiling panels, decoration artwork).

Published

2022

18. Mapping the biotic degradation hazard of wood in Europe – biophysical background, engineering applications, and climate change-induced prospects

Author

Philip B. van Niekerk, Brendan N. Marais, Christian Brischke, Luisa M.S. Borges, Magdalena Kutnik, Jonas Niklewski, David Ansard, Miha Humar, Simon M. Cragg, and Holger Militz

Subjects

Biomaterials

Abstract

Construction using timber has seen a resurgence in light of global climate mitigation policies. Wood is a renewable resource, and engineered wood products are proving to be competitive against concrete and steel while having several advantages. However, while the renewable nature of wood in construction is a beneficial property for climate mitigation policies, the process of biodegradation introduces a challenge for service life planning. A review of hazard mapping is presented while developing contemporary hazard maps, occurrence maps and projected hazard maps for 2050 using representative concentration pathways (RCP) 2.6 and 8.5. The risk of timber decay is expected to increase in most of Europe as the temperatures rise, with a decrease expected in dryer regions. Termites are likely to experience a range expansion as more areas become suitable, while human activity and an increase in extreme weather events like floods are expected to facilitate dispersion. Marine borer species already present a risk in most European coastal regions; however, the effect of changes in water temperatures are likely to shift the boundaries for individual borer species. Overall, warmer climates are expected to increase the metabolic activity of all of these organisms leading to a general reduction in service life.

Published

2021

19. Foil Storage of Storm-Felled Timber—Long-Term Monitoring of Norway Spruce Piles in Germany

Author

Christian Brischke and Kira Wippermann

Subjects

bark-breeding beetle, calamity timber, foil storage, wood quality, Forestry

Abstract

Windthrow and other calamities pose major challenges for forestry companies. In addition to difficult processing, solutions for the medium- and long-term storage of logs without the loss of quality are required in order to counteract the oversupply and falling prices of raw wood. The application of foil piles is a comparatively young and only regionally established procedure, which is of particular interest when wet storage is not possible. As part of a case study, a total of 32 piles of Norway spruce (Picea abies) wood were monitored under foil in the forest district of Dassel (Lower Saxony State Forests, Germany), and the conditions for wood-destroying fungi and the resulting wood quality were evaluated. A considerable depreciation in the stored wood was directly related to the atmosphere inside the pile and could be attributed to various types of damage to the foil. It became evident that quality losses can only be avoided by working quickly, being careful when sealing the piles and providing intensive support in the form of monitoring and rapid repairs.

Published

2022

20. Impact of different sterilization techniques and mass loss measurements on the durability of wood against wood-destroying fungi

Author

Christian Brischke, Susanne Bollmus, and Nicklas von Boch-Galhau

Subjects

Fungal growth, biology, Chemistry, technology, industry, and agriculture, Scots pine, Forestry, Fungus, Contamination, Sterilization (microbiology), biology.organism_classification, Pulp and paper industry, complex mixtures, Durability, Agar plate, Dry weight, General Materials Science

Abstract

The biological durability of wood is frequently determined in laboratory tests with monocultures of different decay fungi under ideal conditions for fungal growth. To avoid contamination with mould and inhibition of fungal growth, wood specimens need to be sterilized using different methods. To determine the mass loss of wood blocks during incubation, the initial total dry mass is needed but should be determined without oven-drying to avoid the loss of volatile compounds of the tested wood. In this study the effect of different sterilization techniques in combination with different methods of determining the oven-dry weight on mass loss (MLF) in agar plate wood block tests was investigated. No significant MLF differences were observed between sterilization through gamma radiation, steam, autoclaving, ethanol dipping and oven-drying. Solely, non-sterilized specimens showed reduced MLF, since the test fungus was inhibited by mould growth. Oven-drying of wood species that contain volatile and resistance-affecting compounds such as Scots pine (Pinus sylvestris) led to reduced biological durability and should either be avoided or adapted to kiln-drying temperatures usually applied in practice.

Published

2021

21. Comparative studies on the durability and moisture performance of wood modified with cyclic N-methylol and N-methyl compounds

Author

Holger Militz, Alexander Ehrmann, Christian Brischke, and Lukas Emmerich

Subjects

040101 forestry, 0106 biological sciences, biology, Moisture, Condensation, Scots pine, Forestry, 04 agricultural and veterinary sciences, Plant Science, Pulp and paper industry, biology.organism_classification, 01 natural sciences, Durability, Industrial and Manufacturing Engineering, chemistry.chemical_compound, chemistry, 010608 biotechnology, Service life, 0401 agriculture, forestry, and fisheries, Glyoxal, General Materials Science, Wetting, Leaching (agriculture)

Abstract

Glyoxal-based condensation resins like 1,3-dimethylol-4,5-dihydroxyethyleneurea (DMDHEU) have been used to modify wood and improve its resistance against decaying fungi. High biological durability of DMDHEU-treated wood has already been confirmed in laboratory and field tests in the past. However, the modes of protective action behind an improved decay resistance are not fully understood yet. Furthermore, it is questionable how the use of formaldehyde-poor N-methylol and formaldehyde-free N-methyl compounds instead of DMDHEU affects the moisture behavior and durability, respectively. In this study, wood blocks were treated with N-methylol (DMDHEU, methylated DMDHEU) and N-methyl compounds (1,3-dimethyl-4,5-dihydroxyethyleneurea; DMeDHEU). Untreated and modified specimens were exposed to different moisture regimes and wood-destroying fungi in order to study the indicators that control changes in the wetting ability and decay resistance. Both N-methylol and N-methyl compounds decreased the water uptake and release and increased the durability of Scots pine sapwood from ‘not durable’ (DC 5) to ‘very durable to durable’ (DC 1–2). However, high fluctuations were observed in water uptake and release as well as mass loss (ML) caused by fungal decay, when modified specimens were tested without passing through a cold-water leaching. Consequently, a significant effect of the leaching procedure according to EN 84 on the durability classification could be established. The latter appeared more pronounced for treatments with N-methyl compounds compared to N-methylol compounds. Finally, wetting ability (kwa) and resistance indicating factors (kinh) enabled a forecast of high biological durability for both treatments with N-methylol and N-methyl compounds under real service life conditions.

Published

2021

22. Wood modification with N-methylol and N-methyl compounds: a case study on how non-fixated chemicals in modified wood may affect the classification of their durability

Author

Christian Brischke, Lukas Emmerich, and Holger Militz

Subjects

040101 forestry, 0106 biological sciences, Biomaterials, Chemistry, 010608 biotechnology, technology, industry, and agriculture, 0401 agriculture, forestry, and fisheries, 04 agricultural and veterinary sciences, Pulp and paper industry, Affect (psychology), complex mixtures, 01 natural sciences, Durability

Abstract

Chemical modification is increasing the durability of wood against biological deterioration. Usually, the effect of a new treatment on the durability of wood is screened in laboratory decay tests, where durability classes are assigned on the basis of the mass loss (ML) caused by degrading fungi. The aim of this study was to demonstrate how non-fixated chemicals in modified wood may affect fungal ML measurements and corresponding durability classification when wood samples are incubated under humid conditions for long periods. Wood blocks were treated with solutions of 1,3-dimethylol-4,5-dihydroxyethyleneurea (DMDHEU), methylated DMDHEU (mDMDHEU) and 1,3-dimethyl-4,5-dihydroxyethyleneurea (DMeDHEU) and subjected to consecutive cold-water leaching cycles. Significant amounts of non-fixated chemicals were removed from the wood by three leaching cycles and might lead to ML mistaken as response of fungal decay. Consequently, the treated material was assigned erroneously by up to four durability classes (DC) worse than material which did not include leachable, non-fixated chemicals. Thus, for a reliable durability classification of chemically modified wood, prolonged leaching procedures are recommended to assure that the measured ML is entirely attributed to fungal decay.

Published

2021

23. Dynamic strength properties and structural integrity of wood modified with cyclic N-methylol and N-methyl compounds

Author

Holger Militz, Susanne Bollmus, Christian Brischke, and Lukas Emmerich

Subjects

0106 biological sciences, Biomaterials, Dynamic strength, Materials science, Chemical engineering, 010608 biotechnology, Structural integrity, 02 engineering and technology, 021001 nanoscience & nanotechnology, 0210 nano-technology, 01 natural sciences

Abstract

Cyclic N-methylol compounds have been used for cell wall impregnation modifications of wood. Besides an improved decay resistance and dimensional stability, the modifications resulted in a decrease of wood’s dynamic strength properties. However, the mechanisms behind a significant loss in dynamic strength are not fully understood yet. In this study, wood blocks were treated with the N-methylol compounds 1,3-dimethylol-4,5-dihydroxyethyleneurea (DMDHEU) and methylated DMDHEU (mDMDHEU) and the N-methyl compound 1,3-dimethyl-4,5-dihydroxy-ethyleneurea (DMeDHEU). In order to study the factors that control the changes of wood performance under dynamic loads, single (impact bending strength, IBS) and multiple dynamic impact (resistance to impact milling, RIM) tests were applied. It became evident, that reductions in IBS and RIM increased with increasing solid content, formaldehyde content and catalyst concentration of the impregnation solutions, but were not affected by a cold-water leaching. Differences in structural integrity of wood modified with N-methylol and N-methyl compounds were more pronounced than those of IBS. Therefore, RIM appeared more sensitive to changes on cellular level, as a higher degree of co-condensation of the N-methylol compounds with cell wall polymers was expected in comparison with the N-methyl compound.

Published

2021

24. Growth behavior of wood-destroying fungi in chemically modified wood: wood degradation and translocation of nitrogen compounds

Author

Sarah Strohbusch, Christian Brischke, Maja Bleckmann, Holger Militz, Susanne Bollmus, and Lukas Emmerich

Subjects

040101 forestry, 0106 biological sciences, Fungal growth, technology, industry, and agriculture, chemistry.chemical_element, Chromosomal translocation, 04 agricultural and veterinary sciences, 15. Life on land, complex mixtures, 01 natural sciences, Nitrogen, Biomaterials, chemistry, Acetylation, 010608 biotechnology, Environmental chemistry, 0401 agriculture, forestry, and fisheries, Degradation (geology)

Abstract

Chemical wood modification has been used to modify wood and improve its decay resistance. However, the mode of protective action is still not fully understood. Occasionally, outdoor products made from chemically modified timber (CMT) show internal decay while their outer shell remains intact. Hence, it was hypothesized that wood decay fungi may grow through CMT without losing their capability to degrade non-modified wood. This study aimed at developing a laboratory test set-up to investigate (1) whether decay fungi grow through CMT and (2) retain their ability to degrade non-modified wood. Acetylated and 1,3-dimethylol-4,5-dihydroxyethyleneurea (DMDHEU) treated wood were used in decay tests with modified ‘mantle specimens’ and untreated ‘core dowels’. It became evident that white rot (Trametes versicolor), brown rot (Coniophora puteana) and soft rot fungi can grow through CMT without losing their ability to degrade untreated wood. Consequently, full volume impregnation of wood with the modifying agent is required to achieve complete protection of wooden products. In decay tests with DMDHEU treated specimens, significant amounts of apparently non-fixated DMDHEU were translocated from modified mantle specimens to untreated wood cores. A diffusion-driven transport of nitrogen and DMDHEU seemed to be responsible for mass translocation during decay testing.

Published

2021

25. Evaluation of the Effect of a Combined Chemical and Thermal Modification of Wood though the Use of Bicine and Tricine

Author

Sandberg, Dennis Jones, Davor Kržišnik, Miha Hočevar, Andreja Zagar, Miha Humar, Carmen-Mihaela Popescu, Maria-Cristina Popescu, Christian Brischke, Lina Nunes, Simon F. Curling, Graham Ormondroyd, and Dick

Subjects

wood, Maillard reaction, thermal/chemical treatment, mechanical properties, infrared spectroscopy, biological properties

Abstract

The effects of thermal modification of wood have been well established, particularly in terms of reductions in mechanical performance. In recent years, there has been an increase in studies related to the Maillard reaction. More commonly associated with food chemistry, it involves the reaction of amines and reducing sugars during cooking procedures. This study has attempted to combine the use of amines and thermal modification, with subsequent properties investigated for the treatment of spruce (Picea abies (L.) H. Karst) and beech (Fagus sylvatica L.). In this initial study, the combined effects of chemical treatments by tricine and bicine were investigated with thermal modification. Along with some preliminary data on mechanical properties, the modifications which appeared in the wood structure were evaluated by infrared spectroscopy and biological studies according to EN113 and EN117 methodologies. The hierarchal study interpretation of FTIR suggested interactions between the bicine or tricine and the wood, which was partly supported by the analysis of volatile organic compounds (VOC), though other tests were not as conclusive. The potential of the method warrants further consideration, which will be described.

Published

2022

26. Effect of size and shape of specimens on the mass loss caused by Coniophora puteana in wood durability tests

Author

Christian Brischke, Susanne Bollmus, and Leopold K. Grünwald

Subjects

biology, Chemistry, Scots pine, Coniophora puteana, Forestry, biology.organism_classification, Durability, Incubation period, %22">Pinus , Horticulture, Specimen volume, General Materials Science, Larch, Incubation

Abstract

The experimental basis for testing the biological durability of wood often includes incubation experiments with wood-destroying basidiomycetes. Numerous parameters can affect the mass loss by fungal decay (MLF) in laboratory durability tests and therefore being decisive for the resulting durability classification. Among others, the dimension of the wood specimen and the time of incubation impact on fungal decay. Hence, both parameters were examined within this study using 19 different specimen formats and four different incubation times. Specimens of larch heartwood (Larix decidua Mill.) were incubated with pure cultures of the brown rot fungus Coniophora puteana. Scots pine sapwood (Pinus sylvestris L.) was used as a reference. The wood specimens’ format turned out to significantly affect both mass loss by fungal decay (MLF) and resulting x-values when MLF of larch was compared with that of the reference Scots pine sapwood. Both measures were highest for specimen formats with moderate surface-volume ratios. MLF and x-values depended on specimen size and shape as well as on the time of incubation. Reducing the specimen volume generally led to higher MLF at a given incubation time, but prolonging incubation times led to higher x-values and thus to lower durability expressed as durability classes (DC). In summary, it appeared highly questionable that results of basidiomycete durability tests can be easily compared to each other when specimen format and/or incubation time deviate from the standard conditions.

Published

2020

27. Resistance of different wood-based materials against mould fungi: a comparison of methods

Author

Carsten Mai, Arne A. P. Imken, Sebastian Kögel, Christian Brischke, and Kim C. Krause

Subjects

040101 forestry, 0106 biological sciences, Plate method, Malt agar, Materials science, Moisture, Forestry, 04 agricultural and veterinary sciences, Solid wood, Pulp and paper industry, 01 natural sciences, respiratory tract diseases, Comparative evaluation, Agar plate, immune system diseases, Chamber method, 010608 biotechnology, Polymer composites, 0401 agriculture, forestry, and fisheries, General Materials Science

Abstract

Wood-based materials are generally prone to colonization by mould fungi and other discoloring microorganisms, but their resistance to fungal discoloration varies. Different standardized test methods for determining the susceptibility to mould fungi have been used to evaluate various wood-based materials, but the obtained results suggest that mould resistance depends on the method applied. Therefore, this study aimed at a comparative evaluation of two commonly used methods for determining the mould resistance of wood-based materials, i.e. the chamber method according to BS 3900—Part G6 and the malt agar plate method according to ISO 16869. Solid wood, wood fiber insulation boards and wood polymer composites were inoculated, incubated for different time intervals, and assessed with regard to superficial mould growth. Mould growth ratings obtained with the two methods did not correlate well, neither within one type of material nor across different materials, which can be attributed to higher moisture contents and additional nutrients available for the specimens in the agar plate test compared to those in the chamber test. It was concluded, that the experimental set up could have an overriding effect on the results of mould resistance tests.

Published

2020

28. Wood durability in terrestrial and aquatic environments – A review of biotic and abiotic influence factors

Author

Holger Militz, Brendan Nicholas Marais, and Christian Brischke

Subjects

040101 forestry, 0106 biological sciences, Abiotic component, Ecology, Aquatic ecosystem, technology, industry, and agriculture, 04 agricultural and veterinary sciences, 15. Life on land, complex mixtures, 01 natural sciences, Durability, 13. Climate action, 010608 biotechnology, 0401 agriculture, forestry, and fisheries, Environmental science, General Materials Science

Abstract

Factors relevant to degradation are important in every wood application. For wood used in ground and water contact; well documented abiotic factors (or agents) include exposure to temperature and m...

Published

2020

29. Effect of Grain Direction on Drilling Resistance Measurements in Wood

Author

Holger Militz, Evgenii Sharapov, and Christian Brischke

Subjects

040101 forestry, 0106 biological sciences, Visual Arts and Performing Arts, Drill, business.industry, Drilling, 04 agricultural and veterinary sciences, Conservation, 01 natural sciences, 010608 biotechnology, Nondestructive testing, Architecture, 0401 agriculture, forestry, and fisheries, Drill bit, Geotechnical engineering, Wood grain, business, Geology

Abstract

An IML-Resi PD-400 drilling tool with two types of spade drill bits (IML System GmbH, Wiesloch, Germany) was used to study the influence of the drilling direction in relation to wood grain orientat...

Published

2020

30. Protecting the heartwood of wood infrastructure – improving performance with borate dual treatments

Author

Adam Taylor, Nathan Irby, Jeff Lloyd, and Christian Brischke

Subjects

040101 forestry, 0106 biological sciences, 010608 biotechnology, 0401 agriculture, forestry, and fisheries, Environmental science, General Materials Science, 04 agricultural and veterinary sciences, Pulp and paper industry, 01 natural sciences, Durability, Dual (category theory)

Abstract

Wood is by far the best structural material in terms of environmental impact. This superiority can be improved if the longevity of the commodity is extended by reducing the decay susceptibility of ...

Published

2020

31. High-energy multiple impact (HEMI) tests of wood–polypropylene composites: new insights in structural integrity

Author

Sarah E. Pilz, Andreas Krause, Kim C. Krause, and Christian Brischke

Subjects

040101 forestry, 0106 biological sciences, High energy, Materials science, Test procedures, Polypropylene composites, technology, industry, and agriculture, Structural integrity, 04 agricultural and veterinary sciences, Microstructure, complex mixtures, 01 natural sciences, 010608 biotechnology, 0401 agriculture, forestry, and fisheries, General Materials Science, Composite material

Abstract

The structural integrity of wood–polymer composites (WPC) has not been fully investigated, which can be attributed to a lack of applicable test procedures. In this study, wood–polypropylene composites were assessed by High-Energy Multiple Impact (HEMI) testing. The acquired composites were based on wood particles from various sources and different wood fibre contents, respectively. With respect to wood fibre content, a clear relationship between resistance to impact milling (RIM) and unnotched impact bending strength (acU) was obtained. The lower the fibre content of the WPC the more structural integrity was retained. In return, various wood sources had no effect on acU, but a major impact on RIM values. RIM is suggested to be predominantly affected by structural features, such as fibre/particle content and characteristics, particle agglomerations, and spatial void distribution.

Published

2020

32. Wood-water relationships and their role for wood susceptibility to fungal decay

Author

Gry Alfredsen and Christian Brischke

Subjects

Wood-water interactions, Brown rot, Vapour pressure of water, chemistry.chemical_element, Fungal degradation, Applied Microbiology and Biotechnology, complex mixtures, Soft rot, Durability, 03 medical and health sciences, chemistry.chemical_compound, Pile test, Mycology, Physiological limit, Wood decomposition, 030304 developmental biology, 0303 health sciences, Moisture, 030306 microbiology, technology, industry, and agriculture, Fungi, General Medicine, Mini-Review, Pulp and paper industry, chemistry, Carbon dioxide, White rot, Minimum moisture threshold, Environmental science, Sorption, Wood-decay fungi, Carbon, Biotechnology

Abstract

Abstract Wood in service is sequestering carbon, but it is principally prone to deterioration where different fungi metabolize wood, and carbon dioxide is released back to the atmosphere. A key prerequisite for fungal degradation of wood is the presence of moisture. Conversely, keeping wood dry is the most effective way to protect wood from wood degradation and for long-term binding of carbon. Wood is porous and hygroscopic; it can take up water in liquid and gaseous form, and water is released from wood through evaporation following a given water vapour pressure gradient. During the last decades, the perception of wood-water relationships changed significantly and so did the view on moisture-affected properties of wood. Among the latter is its susceptibility to fungal decay. This paper reviews findings related to wood-water relationships and their role for fungal wood decomposition. These are complex interrelationships not yet fully understood, and current knowledge gaps are therefore identified. Studies with chemically and thermally modified wood are included as examples of fungal wood substrates with altered moisture properties. Quantification and localization of capillary and cell wall water – especially in the over-hygroscopic range – is considered crucial for determining minimum moisture thresholds (MMThr) of wood-decay fungi. The limitations of the various methods and experimental set-ups to investigate wood-water relationships and their role for fungal decay are manifold. Hence, combining techniques from wood science, mycology, biotechnology and advanced analytics is expected to provide new insights and eventually a breakthrough in understanding the intricate balance between fungal decay and wood-water relations. Key points • Susceptibility to wood-decay fungi is closely linked to their physiological needs. • Content, state and distribution of moisture in wood are keys for fungal activity. • Quantification and localization of capillary and cell wall water in wood is needed. • New methodological approaches are expected to provide new insights

Published

2020

33. Salt Damage in Wood: Controlled Laboratory Exposures and Mechanical Property Measurements

Author

Grant T. Kirker, Samuel L. Zelinka, Christian Brischke, and Leandro Passarini

Subjects

chemistry.chemical_classification, Laboratory methods, Mechanical property, Materials science, Diffusion, Mineral ions, technology, industry, and agriculture, Salt (chemistry), Forestry, complex mixtures, chemistry, Salt water, General Materials Science, Composite material, Porous medium

Abstract

Salt damage in wood can be recognized by its stringy appearance and is frequently observed in wood used in maritime structures and buildings built near the ocean. Whereas salt-damaged wood is common, little is known about the mechanism by which salt water alters the wood structure. There is no information on the effects of salt damage on the mechanical properties of wood. In this study, a laboratory method for creating salt damage in other porous materials was applied to wood. Wood pillars were placed in a reservoir of 5 M NaCl and exposed to a 40% RH environment. Capillary action pulled the salt water to the upper part of the pillars which were dry. Large deposits of effloresced salts were observed. The changes in mechanical properties caused by the salt were measured by the high-energy multiple impact (HEMI) test. Salt damage caused a reduction in the resistance to impact milling (RIM) of 6.5%, and it was concluded that salt damage causes only minor effects on the strength of wood. The tests were not conclusive as the exact mechanism of salt damage in treated wood. However, diffusion of mineral ions through the cell wall was found to be a key step in the salt damage mechanism.

Published

2020

34. Long-term performance of DMDHEU-treated wood installed in different test set-ups in ground, above ground and in the marine environment

Author

Lukas Emmerich, Christian Brischke, and Holger Militz

Subjects

040101 forestry, 0106 biological sciences, Field (physics), Forestry, 04 agricultural and veterinary sciences, Field tests, 01 natural sciences, Durability, Term (time), Above ground, 010608 biotechnology, Test set, 0401 agriculture, forestry, and fisheries, Environmental science, General Materials Science, Geotechnical engineering

Abstract

The field performance of wood modified with 1,3-dimethylol-4,5-dihydroxyethyleneurea (DMDHEU) is reported after outdoor exposure above ground (UC3), in ground (UC4) and in the marine enviro...

Published

2020

35. Anatomical, Physical, Chemical, and Biological Durability Properties of Two Rattan Species of Different Diameter Classes

Author

Sheikh Ali Ahmed, Reza Hosseinpourpia, Christian Brischke, and Stergios Adamopoulos

Subjects

Forest Science, Forestry, white rot, Calamus zollingeri, Calamus ornatus, dynamic vapor sorption, basic density, volumetric swelling, mold, Trävetenskap, Wood Science, QK900-989, Plant ecology

Abstract

Rattan cane is an important forest product with economic value. Its anatomical, physical, and biological properties vary with the cane height. This makes it difficult to select the appropriate cane diameter for harvesting. Understanding the material properties of rattan cane with different diameter sizes is important to enhance its utilization and performance for different end uses. Thus, the present study was performed on two rattan species, Calamus zollingeri and Calamus ornatus, at two different cane heights (bottom/mature and top/juvenile). Calamus zollingeri was studied at diameter classes of 20 mm and 30 mm, while Calamus ornatus was analyzed at a diameter class of 15 mm. The anatomical properties, basic density, volumetric swelling, dynamic moisture sorption, and biological durability of rattan samples were studied. The results showed that C. zollingeri with a 20 mm diameter exhibited the highest basic density, hydrophobicity, dimensional stability, and durability against mold and white-rot (Trametes versicolor) fungi. As confirmed by anatomical studies, this could be due to the higher vascular bundle frequency and longer thick-walled fibers that led to a denser structure than in the other categories. In addition, the lignin content might have a positive effect on the mass loss of different rattan canes caused by white-rot decay.

Published

2022

36. Monitoring of Beech Glued Laminated Timber and Delamination Resistance of Beech Finger-Joints in Varying Ambient Climates

Author

Militz, Hannes Stolze, Mathias Schuh, Sebastian Kegel, Connor Fürkötter-Ziegenbein, Christian Brischke, and Holger

Subjects

beech glulam, monitoring experiment, finger-joint bonding, delamination, adhesives

Abstract

In this study, varying ambient climates were simulated in a test building by changing temperature and relative humidity. Beech glued laminated timber (glulam, Fagus sylvatica, L.) was freshly installed in the test building and monitoring of the change in wood moisture content of the glulam resulting from the variations in climate was carried out. Subsequently, finger-jointed beech specimens were exposed to the variations in relative humidity measured in the course of the monitoring experiment on a laboratory scale, and thus an alternating climate regime was derived from the conditions in the test building. Its influence on the delamination of the finger-joints was evaluated. In addition, it was examined whether beech finger-joints using commercial adhesive systems fulfil the normative requirements for delamination resistance according to EN 301 (2018) and whether different bonding-wood moisture levels have an effect on the delamination of the finger-joints. In the context of the monitoring experiment, there was a clear moisture gradient in the beech glulam between the inner and near-surface wood. The applied adhesive systems showed almost the same delamination resistance after variation of relative humidity. The normative requirements were met by all PRF-bonded and by most PUR-bonded beech finger-joints with higher bonding wood moisture content.

Published

2021

37. Monitoring of Beech Glued Laminated Timber and Delamination Resistance of Beech Finger-Joints in Varying Ambient Climates

Author

Hannes Stolze, Mathias Schuh, Sebastian Kegel, Connor Fürkötter-Ziegenbein, Christian Brischke, and Holger Militz

Subjects

monitoring experiment, beech glulam, finger-joint bonding, adhesives, QK900-989, Plant ecology, delamination

Abstract

In this study, varying ambient climates were simulated in a test building by changing temperature and relative humidity. Beech glued laminated timber (glulam, Fagus sylvatica, L.) was freshly installed in the test building and monitoring of the change in wood moisture content of the glulam resulting from the variations in climate was carried out. Subsequently, finger-jointed beech specimens were exposed to the variations in relative humidity measured in the course of the monitoring experiment on a laboratory scale, and thus an alternating climate regime was derived from the conditions in the test building. Its influence on the delamination of the finger-joints was evaluated. In addition, it was examined whether beech finger-joints using commercial adhesive systems fulfil the normative requirements for delamination resistance according to EN 301 (2018) and whether different bonding-wood moisture levels have an effect on the delamination of the finger-joints. In the context of the monitoring experiment, there was a clear moisture gradient in the beech glulam between the inner and near-surface wood. The applied adhesive systems showed almost the same delamination resistance after variation of relative humidity. The normative requirements were met by all PRF-bonded and by most PUR-bonded beech finger-joints with higher bonding wood moisture content.

Published

2021

38. Biological Durability of Wood–Polymer Composites—The Role of Moisture and Aging

Author

Andreas Buschalsky, Christian Brischke, Kim Christian Klein, Thomas Kilian, and Holger Militz

Subjects

wood–polymer composites, WPC, biological durability, durability test, EN 15534-1, basidiomycetes, soft rot, wood–moisture interaction, General Materials Science

Abstract

Knowledge about the resistance of wood–polymer composites (WPCs) to biological attack is of high importance for purpose-oriented use in outdoor applications. To gain this knowledge, uniform test methods are essential. EN 15534-1 (2018) provides a general framework, including the recommendation of applying a pre-weathering procedure before the biological laboratory tests. However, the procedure’s manner is not specified, and its necessity assumes that a durability test without such pre-weathering will not produce the structural changes that occur during outdoor use. To verify this assumption, this study examined the influence of natural, ground-level pre-weathering on the material properties of different WPC variants, which were tested at intervals of six months in four durability tests under laboratory conditions in accordance with EN 15534-1 (2018). Weathering factors were calculated from determined characteristic values such as mass loss, and loss in moduli of elasticity (MOE) and rupture (MOR). The weathering factors based on mechanical properties tended to decrease with increasing weathering duration. The expected negative influence of pre-weathering on these material properties was thus not confirmed. The weathering factors based on mass loss were subject to high variation. No significant effect of pre-weathering on mass loss due to fungal attack became evident. Overall, the necessity of a pre-weathering step in biological durability tests shall be questioned based on the presented results.

Published

2022

39. Durability and protection of timber structures in marine environments in Europe: An overview

Author

Lone Ross Gobakken, John R. Williams, Erik Larnøy, Per-Otto Flæte, Miha Humar, Simon M. Cragg, Andreas Treu, Foued Aloui, Katrin Zimmer, Luisa M. S. Borges, Mats Westin, and Christian Brischke

Subjects

0106 biological sciences, Environmental Engineering, Bioengineering, Marine invertebrates, 15. Life on land, Protection system, 01 natural sciences, Durability, Aquatic organisms, Environmental protection, 010608 biotechnology, Environmental science, 14. Life underwater, Waste Management and Disposal, 010606 plant biology & botany

Abstract

Timber structures in marine applications are often exposed to severe degradation conditions caused by mechanical loads and wood-degrading organisms. This paper presents the use of timber in marine environments in Europe from a wood protection perspective. It discusses the use of wood in coastline protection and archeological marine wood, reviews the marine borer taxa in European waters, and gives an overview of potential solutions for protection of timber in marine environments. Information was compiled from the most relevant literature sources with an emphasis on new wood protection methods; the need for research and potential solutions are discussed. Traditionally, timber has been extensively utilized in a variety of marine applications. Although there is a strong need for developing new protection systems for timber in marine applications, the research in this field has been scarce for many years. New attempts to protect timber used in marine environments in Europe have mainly focused on wood modification and the use of mechanical barriers to prevent colonization of marine wood borers. The importance of understanding the mechanisms of settlement, migration, boring, and digestion of the degrading organisms is key for developing effective systems for protecting timber in marine environments.

Published

2019

40. Impact of drill bit feed rate and rotational frequency on the evaluation of wood properties by drilling resistance measurements

Author

Holger Militz, Aleksandr Toropov, Christian Brischke, and Evgenii Sharapov

Subjects

040101 forestry, Wood cutting, Materials science, business.industry, 0211 other engineering and technologies, Mechanical engineering, Drilling, Forestry, 04 agricultural and veterinary sciences, 02 engineering and technology, Rotational frequency, Cutting force, Nondestructive testing, 021105 building & construction, 0401 agriculture, forestry, and fisheries, Drill bit, General Materials Science, business

Abstract

IML-Resi PD-400 drilling tools (IML System GmbH, Wiesloch, Germany) were used to study the influence of the feed rate and the rotational frequency of the drill bit on the drilling resistanc...

Published

2019

41. Prediction of modulus of elasticity in static bending and density of wood at different moisture contents and feed rates by drilling resistance measurements

Author

Evgenii Sharapov, Elena Smirnova, Holger Militz, and Christian Brischke

Subjects

Materials science, biology, Moisture, Scots pine, Drilling, Forestry, Young's modulus, biology.organism_classification, symbols.namesake, Fagus sylvatica, symbols, General Materials Science, Composite material, Saturation (chemistry), Beech, Water content

Abstract

An IML-RESI PD 400 drilling tool and a standard spade drill bit were used to find the correlations of drilling and feeding resistance with the modulus of elasticity in static bending and density of wood. In total, 1575 drillings at 0.5, 1.0 and 1.5 m/min feed rates were made in specimens of Scots pine (Pinus sylvestris L.), European beech (Fagus sylvatica L.), English oak (Quercus robur L.) and common lime (Tilia europaea L.), which were oven-dried, conditioned at 20 °C/65% RH and 20 °C/95% RH and vacuum-impregnated with water. The feed rate (feed rate per major cutting edge or uncut chip thickness) had a significant impact on the prediction of density and modulus of elasticity through drilling resistance measurements and should be considered for comparison of properties and internal conditions of wood. Because of stronger correlation between drilling resistance and tested wood properties compared to feeding resistance, drilling resistance is recommended for density and MOE prediction of sound wood. Moisture content had no significant impact on the modulus of elasticity prediction by the drilling resistance measurements, while density can be predicted by linear models for two stages of moisture content variation, below and above fibre saturation.

Published

2019

42. Numerical study on the effects of macro climate and detailing on the relative decay hazard of Norway spruce

Author

Christian Brischke, Eva Frühwald Hansson, and Jonas Niklewski

Subjects

040101 forestry, 0106 biological sciences, 13. Climate action, Environmental protection, 010608 biotechnology, 0401 agriculture, forestry, and fisheries, Environmental science, General Materials Science, 04 agricultural and veterinary sciences, Macro, 01 natural sciences, Hazard, Durability

Abstract

The durability of wood depends on its in-use environmental conditions. The aim of this study was to estimate the effects associated with macro climate and detail design as well as their interdepend...

Published

2019

43. Abrasion Resistance of Thermally and Chemically Modified Timber

Author

Susanne Bollmus, Christian Brischke, and Neele Ziegeler

Subjects

010302 applied physics, Materials science, 0103 physical sciences, technology, industry, and agriculture, Forestry, 02 engineering and technology, 15. Life on land, Composite material, 021001 nanoscience & nanotechnology, 0210 nano-technology, 01 natural sciences

Abstract

Wood modification is an appropriate way of improving the natural durability and dimensional stability of wood without the use of biocides. Different thermal and chemical wood modification processes are available for this purpose, very differently affecting the structural integrity of wood. In this study, thermally modified, melamine resin treated, acetylated, furfurylated, and mDMDHEU treated wood underwent abrasion tests according to two different methods representing different loads in practice. The Taber Abraser method caused crosswise cutting into the wood surface, while the Shaker method challenged mainly the specimen edges with dynamic loads. Abrasion resistance of wood was affected by all types of cell wall modification, but the effects were strongly dependent on the type of modification and the applied load type. For characterising the suitability of wooden materials with respect to wear resistance under outdoor conditions, it is recommended to apply a set of methods rather than a single test procedure to fully reflect the loads occurring in practice.

Published

2019

44. Evaluation of Moisture and Decay Models for a New Design Framework for Decay Prediction of Wood

Author

Jonas Niklewski, Philip Bester van Niekerk, Christian Brischke, and Eva Frühwald Hansson

Subjects

detailing, modelling, moisture, performance based, durability, QK900-989, Plant ecology, wood, decay

Abstract

Performance-based, service-life design of wood has been the focus of much research in recent decades. Previous works have been synthesized in various factorized design frameworks presented in the form of technical reports. Factorization does not consider the non-linear dependency between decay-influencing effects, such as between detail design and climate variables. The CLICKdesign project is a joint European effort targeting digital, performance-based specification for service-life design (SLD) of wood. This study evaluates the feasibility of using a semi-empirical moisture model (SMM) as a basis for a digital SLD framework. The performance of the SMM is assessed by comparison against a finite element model (FEM). In addition, two different wood decay models (a logistic, LM, and simplified logistic model (SLM)) are compared. While discrepancies between the SMM and FEM were detected particularly at high wood moisture content, the overall performance of the SMM was deemed sufficient for the application. The main source of uncertainty instead stems from the choice of wood decay model. Based on the results, a new method based on pre-calculated time series, empirical equations, and interpolation is proposed for predicting the service life of wood. The method is fast and simple yet able to deal with non-linear effects between weather variables and the design of details. As such, it can easily be implemented as part of a digital design guideline to provide decision support for architects and engineers, with less uncertainty than existing factorized guidelines.

Published

2021

45. Estimating the Service Life of Timber Structures Concerning Risk and Influence of Fungal Decay—A Review of Existing Theory and Modelling Approaches

Author

Philip Bester van Niekerk, Christian Brischke, and Jonas Niklewski

Subjects

modelling, service life planning, fungi, QK900-989, Plant ecology, decay, wood

Abstract

Wood is a renewable resource and a promising construction material for the growing bio-based economy. Efficiently utilising wood in the built environment requires a comprehensive understanding of the dynamics regarding its usability. Durability is an essential property to consider, as various types of exposure create conditions for the deterioration of wood through biotic and abiotic agents. Biodegradable materials introduce increased complexity to construction and design processes, as material decomposition during a structure’s lifetime presents a physical risk to human health and safety and costs related to repairs and maintenance. Construction professionals are thus tasked with utilising wooden elements to accentuate the material’s beneficial properties while reducing the risk of in-service decomposition. In this paper, only the cause and effect of fungal induced decay on the service life of wooden buildings and other wood-based construction assets are reviewed. The service life of wood components can thus be extended if suitable growing conditions are controlled. Multiple existing modelling approaches are described throughout the text, with special attention given to the two most comprehensive ones; TimberLife and the WoodExter. In choosing an appropriate model for a specific application, the authors recommend evaluating the model’s regional specificity, complexity, practicality, longevity and adaptability.

Published

2021

46. Studies into Fungal Decay of Wood in Ground Contact—Part 2: Development of a Dose–Response Model to Predict Decay Rate

Author

Brendan Nicholas Marais, Philip Bester van Niekerk, and Christian Brischke

Subjects

soil temperature, soil water-holding capacity, in-ground wood decay, soil moisture content, regression, QK900-989, Plant ecology, complex mixtures

Abstract

In this article a dose–response model was developed to describe the effect of soil temperature, soil moisture content, and soil water-holding capacity, on the decay of European beech (Fagus sylvatica) wood specimens exposed to soil contact. The developed dose–response model represents a step forward in incorporating soil-level variables into the prediction of wood decay over time. This builds upon prior models such as those developed within the TimberLife software package, but also aligns with similar modeling methodology employed for wood exposed above ground. The model was developed from laboratory data generated from terrestrial microcosm trials which used test specimens of standard dimension, incubated in a range of soil conditions and temperatures, for a maximum period of 16 weeks. Wood mass loss was used as a metric for wood decay. The dose aspect of the developed function modelled wood mass loss in two facets; soil temperature against wood mass loss, and soil water-holding capacity and soil moisture content against wood mass loss. In combination, the two functions describe the wood mass loss as a function of a total daily exposure dose, accumulated over the exposure period. The model was deemed conservative, delivering an overprediction of wood decay, or underprediction of wood service-life, when validated on a similar, but independent dataset (R2 = 0.65). Future works will develop similar models for outdoor, field-trial datasets as a basis for service-life prediction of wooden elements used in soil contact.

Published

2021

47. Modelling the Material Resistance of Wood—Part 1: Utilizing Durability Test Data Based on Different Reference Wood Species

Author

Christian Brischke, Gry Alfredsen, Katrin Zimmer, Miha Humar, Brendan Nicholas Marais, and Robert F. A. Stein

Subjects

0106 biological sciences, prostotrosnice, soft rot, white rot, razkroj, 01 natural sciences, Fagus sylvatica, durability, brown rot, 010608 biotechnology, bela trohnoba, QK900-989, udc:630*8, Plant ecology, moisture dynamics, Beech, Trametes versicolor, 040101 forestry, fungal decay, mehka trohnoba, biology, Resistance (ecology), Moisture, odpornost, Scots pine, Forestry, Picea abies, basidiomycetes, brown rot, 04 agricultural and veterinary sciences, 15. Life on land, dinamika navlaževanja, biology.organism_classification, Durability, Horticulture, rjava trohnoba, durability, 0401 agriculture, forestry, and fisheries, Environmental science

Abstract

To evaluate the performance of new wood-based products, reference wood species with known performances are included in laboratory and field trials. However, different wood species vary in their durability performance, and there will also be a within-species variation. The primary aim of this paper was to compare the material resistance against decay fungi and moisture performance of three European reference wood species, i.e., Scots pine sapwood (Pinus sylvestris), Norway spruce (Picea abies), and European beech (Fagus sylvatica). Wood material was collected from 43 locations all over Europe and exposed to brown rot (Rhodonia placenta), white rot (Trametes versicolor) or soft rot fungi. In addition, five different moisture performance characteristics were analyzed. The main results were the two factors accounting for the wetting ability (kwa) and the inherent protective properties of wood (kinh), factors for conversion between Norway spruce vs. Scots pine sapwood or European beech for the three decay types and four moisture tests, and material resistance dose (DRd) per wood species. The data illustrate that the differences between the three European reference wood species were minor, both with regard to decay and moisture performance. The results also highlight the importance of defined boundaries for density and annual ring width when comparing materials within and between experiments. It was concluded that with the factors obtained, existing, and future test data, where only one or two of the mentioned reference species were used, can be transferred to models and prediction tools that use another of the reference species.

Published

2021

48. Predicting the Outdoor Moisture Performance of Wood Based on Laboratory Indicators

Author

Manuel S. Schulz, Anne-Cathrin Jaeger, Lukas Emmerich, Miha Humar, Marten Sievert, Christian Brischke, and Arne Beulshausen

Subjects

0106 biological sciences, material resistance, Preservative, EN 16818, vrednotenje življenjske dobe, Field tests, service life prediction, 01 natural sciences, residual moisture content, 010608 biotechnology, Water uptake, udc:630*1, absorption-desorption tests, Water content, 040101 forestry, Moisture, Residual moisture, Forestry, lcsh:QK900-989, 04 agricultural and veterinary sciences, Pulp and paper industry, testi adsorpcije in desorpcije, odpornost lesa, Permeability (earth sciences), Service life, lcsh:Plant ecology, 0401 agriculture, forestry, and fisheries, Environmental science, vlažnost lesa

Abstract

The service life of wood in outdoor use under humid conditions is mainly determined by its material resistance and the exposure situation. Different standards such as EN 350 (2016) point on the relevance of wood&rsquo, s resistance against moisture for its expected service life. Recently, different standardized but also numerous nonstandardized methods were suggested to test the water permeability of wooden materials. In the context of this study, different European-grown soft- and hardwoods, tropical hardwoods, modified wood and wood treated with water- and oil-borne preservatives were subjected to floating and submersion tests according to CEN/TS 16818 (2018) and different short-term water uptake and release tests. Moisture performance data from field tests with the same materials were analyzed and used to assess the predictive power of different laboratory moisture indicators. The moisture characteristics suggested by CEN/TS 16818 (2018)&mdash, rm168 (residual moisture content after water uptake and release processes) and res312 (residue as a percentage of the absorbed moisture)&mdash, showed the little potential to predict the outdoor moisture performance of the tested materials. In contrast, the mean moisture content during absorption and desorption (MCmean) predicted well the outdoor moisture performance of the materials under test. Short-term water uptake and release of small specimens also showed high predictive power.

Published

2020

49. Quality Control of Thermally Modified Timber Using Dynamic Vapor Sorption (DVS) Analysis

Author

Rožle Repič, Lukas Emmerich, Boštjan Lesar, Romana Cerc Korošec, Gregor Rep, Christian Brischke, Miha Humar, and Davor Kržišnik

Subjects

0106 biological sciences, dinamična sorpcija vodne pare, Materials science, 01 natural sciences, kontrola kakovosti, termična modifikacija, Fagus sylvatica, les, Aluminium foil, 010608 biotechnology, Thermal, dynamic vapour sorption, udc:630*8, quality control, Beech, Water content, moisture content, 040101 forestry, biology, Forestry, Picea abies, 04 agricultural and veterinary sciences, lcsh:QK900-989, Pulp and paper industry, biology.organism_classification, thermal modification, Laboratory oven, lcsh:Plant ecology, 0401 agriculture, forestry, and fisheries, Dynamic vapor sorption, vlažnost lesa, wood

Abstract

The importance of thermal modification is increasing worldwide. Increased use of thermally modified timber (TMT) has resulted in a need for reliable quality control, comprising control of variation of the production within defined limits, allowing third-party control in the case of certification and the regulation of customer complaints and claims. Techniques are thus needed to characterise the modification of quality in terms of improved target properties of TMT during industrial production, and of TMT products that have been in service for an arbitrary time. In this study, we aimed to utilise dynamic vapor sorption (DVS) for this purpose. Norway spruce (Picea abies) and European beech (Fagus sylvatica) samples were thermally modified at different temperatures according to different heat treatment techniques: (1) the Silvapro process based on an initial vacuum, (2) an air heat treatment, whereby samples were wrapped in aluminium foil, (3) thermal modification of wood samples in the ambient atmosphere in a laboratory oven. Wood samples from closed processes were analysed for validation. TMT was characterised with respect to mass loss, colour and density. Mass loss of wood due to modification (MLTM) was correlated with factors derived from DVS analysis. The present DVS measurements suggest that the equilibrium wood moisture content (EMC95% RH), the time to reach 10% wood moisture content (t10% MC), and the elongation factor, c, derived from a logarithmic function, can serve as alternative parameters to characterise the quality of several thermal modification processes. Further studies are recommended using other wood species, different modification processes and further parameters gained from DVS measurements to understand the robustness and the predictive power of the applied technique.

Published

2020

50. Mapping the Decay Hazard of Wooden Structures in Topographically Divergent Regions

Author

Vanessa Selter and Christian Brischke

Subjects

0106 biological sciences, service life modelling, Moisture, service life planning, 0211 other engineering and technologies, High resolution, Forestry, 02 engineering and technology, Fungal degradation, lcsh:QK900-989, 01 natural sciences, Hazard, Climate index, Altitude, 010608 biotechnology, Scheffer Climate Index (SCI), 021105 building & construction, lcsh:Plant ecology, Environmental science, durability, Physical geography, climate

Abstract

The service life of exposed wooden structures depends on many endogenous and exogenous factors with moisture being key for fungal degradation. Climate parameters are therefore important input variables for modelling fungal decay in wood. In recent years, different approaches aimed at modelling climate-induced dosage on the material climate (i.e., exposure models) and the effect of the latter on fungal decay (i.e., decay models). Based on maps of Europe, North America or Australia, the decay hazard can be assigned to zones and used for estimating the relative decay potential of an arbitrary location. However, especially in topographically divergent regions, the climate-induced decay hazard can vary strongly within a small area. Within this study, decay hazards were quantified and mapped for a mountainous region where topography-induced differences in local climate and corresponding exposure dosage can be expected. The area under investigation was Switzerland. In addition to the Scheffer Climate Index (SCI), two exposure models were combined with two decay models and used to quantify the relative moisture- and temperature-induced exposure dose at 75 different weather stations in Switzerland and adjacent regions. The exposure was expressed as relative dosage with Uppsala (Sweden) as a reference location. Relative dose values were calculated for locations between weather stations using an &lsquo, inverse distance weighted (IDW)&rsquo, interpolation and displayed in maps for the entire country. A more detailed analysis was undertaken for the L&ouml, tschental area, which is the largest valley on the northern side of the Rh&ocirc, ne valley in the canton of Valais. The relative dose differed strongly within small areas and altitude was well correlated with the average annual temperature and the resulting relative dose. It became evident that small-scale mapping with high resolution is needed to fully reflect the impact of topography and other local conditions on the moisture- and temperature-induced decay risk in wooden components.

Published

2020