Your search keyword '"Liselotte De Ligne"' showing total 8 results

1. Moisture Dynamics of Wood-Based Panels and Wood Fibre Insulation Materials

Author

Liselotte De Ligne, Joris Van Acker, Jan M. Baetens, Salah Omar, Bernard De Baets, Lisbeth G. Thygesen, Jan Van den Bulcke, and Emil E. Thybring

Subjects

moisture dynamics, wood-based panels, wood fibre insulation, service life, X-ray CT, LFNMR, Plant culture, SB1-1110

Abstract

Moisture performance is an important factor determining the resistance of wood-based building materials against fungal decay. Understanding how material porosity and chemistry affect moisture performance is necessary for their efficient use, as well as for product optimisation. In this study, three complementary techniques (X-ray computed tomography, infrared and low-field NMR spectroscopy) are applied to elucidate the influence of additives, manufacturing process and material structure on the liquid water absorption and desorption behaviour of a selection of wood-based panels, thermally modified wood and wood fibre insulation materials. Hydrophobic properties achieved by thermal treatment or hydrophobic additives such as paraffin and bitumen, had a major influence on water absorption and desorption rates. When hydrophobic additives did not play a role, pore distributions and manufacturing process had a decisive influence on the amount and rate of absorption and desorption. In that case, a higher porosity resulted in a higher water absorption rate. Our results show that there is a clear potential for tailoring materials towards specific moisture performance by better understanding the influence of different material characteristics. This is useful both for achieving desired moisture buffering as well as to increase service life of wood-based materials. From a sustainability perspective, fit-for-purpose moisture performance is often easier to achieve and preferred than wood protection by biocide preservative treatments.

Published

2022

2. Analysis of spatio-temporal fungal growth dynamics under different environmental conditions

Author

Liselotte De Ligne, Guillermo Vidal-Diez de Ulzurrun, Jan M. Baetens, Jan Van den Bulcke, Joris Van Acker, and Bernard De Baets

Subjects

Time series analysis, Temperature, Relative humidity, Fungal networks, Coniophora puteana, Rhizoctonia solani, Botany, QK1-989

Abstract

Abstract Traditionally, fungal growth dynamics were assessed manually, limiting the research to a few environmental conditions and/or fungal species. Fortunately, more automated ways of measurement are gaining momentum due to the availability of cheap imaging and processing equipment and the development of dedicated image analysis algorithms. In this paper, we use image analysis to assess the impact of environmental conditions on the growth dynamics of two economically important fungal species, Coniophora puteana and Rhizoctonia solani. Sixteen environmental conditions combining four temperatures (15, 20, 25 and 30 °C) and four relative humidity (RH) conditions (65, 70, 75 and 80% RH) were tested. Fungal growth characteristics were extracted from images of the growing fungi, taken at regular points in time. Advanced time series analysis was applied to quantitatively compare the effect of the environmental conditions on these growth characteristics. The evolution of the mycelial area and the number of tips over time resulted in typical sigmoidal growth curves. Other growth characteristics such as the mean hyphal segment length did not vary significantly over time. Temperature and RH usually had a combined effect on the growth dynamics of the mycelial area and the number of tips. When defining optimal growth conditions for a fungus, it is therefore of primordial importance that the effect of temperature and RH is assessed simultaneously. At the most extreme conditions we tested, the mycelium most probably experienced water stress when developing over the inert Petri dish surface. An RH of 65% (independent of temperature) for C. puteana and a temperature of 30 °C (independent of RH) for both C. puteana and R. solani therefore always resulted in limited fungal growth, while the optimal growing conditions were at 20 °C and 75% RH and at 25 °C and 80% RH for R. solani and at 20 °C and 75% RH for C. puteana. The method applied in this study offers an updated and broader alternative to classical and narrowly focused studies on fungal growth dynamics, and is well suited to efficiently assess the effect of environmental conditions on fungal growth.

Published

2019

3. Studying the spatio-temporal dynamics of wood decay with X-ray CT scanning

Author

Liselotte De Ligne, Amélie De Muynck, Jordy Caes, Jan M. Baetens, Bernard De Baets, Luc Van Hoorebeke, Joris Van Acker, and Jan Van den Bulcke

Subjects

Biomaterials

Abstract

Bio-based building materials are susceptible to degradation by decay fungi when exposed to favourable conditions for fungal growth. The risk of decay depends on both the environmental conditions and material resistance. Although durability data is available for solid wood, standard tests mainly focus on mass loss assessment after a fixed degradation period. In-depth knowledge on time-dependent decay patterns is lacking, yet could prove relevant for optimisations of the structural design of engineered wood products to increase their service life. Here, a novel X-ray CT scanning set-up and analysis pipeline for non-destructive assessment of the influence of material structure on temporal decay patterns under laboratory conditions is presented. Wood specimens that were severely degraded showed a pattern in which the density decreased substantially after 2 weeks, due to wood mass being metabolised into mycelium, carbon dioxide and water. The influence of various anatomical features, such as the vessel orientation and the number of growth rings, on wood degradation patterns was demonstrated. This approach is a starting point for further in-depth research on the influence of material structure on decay. The method is especially interesting to assess the efficacy of structural modification strategies that are expected to inhibit decay or enhance service life.

Published

2022

4. Unraveling the natural durability of wood: revealing the impact of decay-influencing characteristics other than fungicidal components

Author

Jan M. Baetens, Gang Wang, Liselotte De Ligne, Jan Van den Bulcke, Imke De Windt, Hans Beeckman, Bernard De Baets, and Joris Van Acker

Subjects

0106 biological sciences, 0303 health sciences, biology, Chemistry, Industrial chemistry, biology.organism_classification, Pulp and paper industry, 01 natural sciences, Durability, Biomaterials, Fungicide, 03 medical and health sciences, Entandrophragma, 010608 biotechnology, Aucoumea klaineana, 030304 developmental biology

Abstract

The effect of fungicidal components in wood has been known for ages, yet there is no method to assess the impact of such components on the durability of a wood species, as compared to other material characteristics that influence decay. In this paper, the importance of fungicidal effects on the natural durability of 10 wood species is assessed in relation to other decay-influencing factors with a new test, the so-called ‘paste test’. By comparing results from this test with the ‘mini-block test’, on both heartwood and leached sapwood, insight is gained into the significance of fungicidal components on the one hand and other material characteristics on the other hand. The durability of species such as Prunus avium was attributed mainly to fungicidal components. For species such as Pterocarpus soyauxii, durability seemed to be an effect of both fungicidal components and moisture-regulating components, while the latter seemed to be of main importance in regulating the decay of Aucoumea klaineana and Entandrophragma cylindricum. Wood-anatomical features, such as the parenchyma content (in case of brown rot fungi) and the vessel-fiber ratio, possibly affect degradation as well. This work shows that fungicidal components are not always of major importance for the durability of a wood species. The authors hereby emphasize the importance of moisture-regulating components and wood anatomy on the durability of wood.

Published

2020

5. Bio-Based Building Materials-How to Unravel the Role of Material Characteristics on Fungal Susceptibility?

Author

Jan M. Baetens, Jan Van den Bulcke, Joris Van Acker, Bernard De Baets, Liselotte De Ligne, Serrat, Carles, Casas, Joan Ramon, and Gibert, Vicente

Subjects

Fungal growth, Technology and Engineering, Moisture, Structural integrity, New materials, Bio based, X-Ray CT, Material Characteristics, Fungal Degradation, Sustainability, Environmental science, Bio-Based Building Materials, Biochemical engineering, Building industry, Renewable resource

Abstract

Bio-based materials are gaining importance in the building industry, as the focus on sustainability and life-cycle-assessment has increased substantially over the last decade. Wood and wood-engineered products as well as insulation materials made from cellulose, wood, flax, hemp, etc. are increasingly used. These materials are made from renewable resources and with considerably lower energy consumption than various other building materials, such as insulation polymers, steel and concrete. As steel can corrode and concrete can rot, so can bio-based building materials degrade over time when exposed to those conditions that favour decay. Since fungi cause not only aesthetical degradation, but can also severely compromise the structural integrity of a building component this is critical for any service life approach. Consequently, a proper understanding of the fungal susceptibility of bio-based materials is needed, both for optimal application of bio-based materials as for the design of new materials. Based on a combination of tests we try to unravel the role of the material’s chemical components, structure and moisture dynamics on its fungal susceptibility, as well as the interaction between those material characteristics. In a first test set-up, the ‘paste test’, the material’s structure is removed and fungal growth is assessed over time in 2D, with only the material’s chemical components playing a role. In the second test set-up, the ‘X-ray CT test’, fungal development is assessed non-destructively in 3D with X-ray CT, giving an indication of moisture production and distribution over time, in relation to the material’s structure. By comparing the results, we have a better idea of how much each material characteristic influences fungal susceptibility. This knowledge can then be used for optimising fungal testing of bio-based materials, ensuring optimal application and providing the building industry with the confidence they need to pave the way to a more sustainable future.

Published

2020

6. Counter-intuitive response to water limitation in a Southern European Provenance of Frangula alnus Mill. in a common garden experiment

Author

Jan Van den Bulcke, Kristine Vander Mijnsbrugge, Matteo Campioli, Lise De Clerck, Kathy Steppe, Stefaan Moreels, Liselotte De Ligne, Amy Lauwers, and Nele Van der Schueren

Subjects

0106 biological sciences, Agriculture and Food Sciences, plant architecture, leaf senescence, Drought tolerance, ved/biology.organism_classification_rank.species, Growing season, drought, Biology, SESSILE OAK, 010603 evolutionary biology, 01 natural sciences, Shrub, CARBOHYDRATE RESERVES, ROBUR, Frangula alnus, Cutting, DROUGHT TOLERANCE, TREE, Transpiration, 2. Zero hunger, CLIMATE-CHANGE, ved/biology, general linear mixed models, fungi, food and beverages, Forestry, lcsh:QK900-989, 15. Life on land, biology.organism_classification, DIFFERENTIATION, Agronomy, 13. Climate action, glossy buckthorn, post-drought recovery, QUERCUS-PETRAEA, Shoot, lcsh:Plant ecology, GROWTH, POPULATIONS, common garden, Pruning, bud burst, 010606 plant biology & botany

Abstract

Climate change will intensify drought periods during the growing season in Western Europe. We mimicked this prediction by withholding water in summer from young rooted cuttings of Frangula alnus Mill., a common shrub species, originating from different latitudes in Europe (Italy, Belgium and Sweden) and growing in a common garden environment in Belgium. We followed the responses to the drought up to two years after the treatment. Counter-intuitively, the Italian provenance displayed earlier symptoms and stronger effects of water limitation than the other two provenances. A putative higher transpiration in this provenance could be suggested based on a relative larger shoot growth, larger leaves and a higher stomatal density. After the post-drought re-watering, the droughted plants of the Italian provenance entered leaf senescence later than the control plants, likely as a compensation mechanism for the lost growing time. Bud burst in the first year after the drought treatment and leaf senescence in the next autumn were both advanced in the drought treated group when compared with the control plants. Bud burst in the second year after the drought treatment did not display any differentiation anymore between control and drought treated plants. Growth traits also displayed legacies of the water limitation. For example, the drought treated plants showed a lower number of reshoots upon pruning in the year after the drought treatment. Our results suggest that assisted migration from southern Europe to western Europe as a climate change adaptation strategy might not always follow the expected patterns.

Published

2020

7. Assessing the nutrient value of bio-based materials in relation to early fungal growth

Author

Liselotte De Ligne, Jan Van den Bulcke, Jan Baetens, Bernard De Baets, and Acker, Joris

Subjects

bio-based materials, nutrient value, image analysis, Biology and Life Sciences, material characteristics, fungal susceptibility

8. Assessment of the combined effect of temperature and relative humidity on fungal growth

Author

Liselotte De Ligne, Vidal Diez Ulzurrun, Guillermo, Jan Baetens, Jan Van den Bulcke, Acker, Joris, and Bernard De Baets

Subjects

mycology, Biology and Life Sciences, Bio-imaging, fungal growth, environmental conditions