Growing mallee eucalypts as short-rotation tree crops in the semi-arid wheatbelt of Western Australia

Wildy, Daniel Thomas

January 2004

[Truncated abstract] Insufficient water use by annual crop and pasture species leading to costly rises in saline watertables has prompted research into potentially profitable deep-rooted perennial species in the Western Australian wheatbelt. Native mallee eucalypts are currently being developed as a short-rotation coppice crop for production of leaf oils, activated carbon and bio-electricity for low rainfall areas (300—450 mm) too dry for many of the traditional timber and forage species. The research in this study was aimed at developing a knowledge base necessary to grow and manage coppiced mallee eucalypts for both high productivity and salinity control. This firstly necessitated identification of suitable species, climatic and site requirements favourable to rapid growth, and understanding of factors likely to affect yield of the desirable leaf oil constituent, 1,8-cineole. This was undertaken using nine mallee taxa at twelve sites with two harvest regimes. E. kochii subsp. plenissima emerged as showing promise in the central and northern wheatbelt, particularly at a deep acid sand site (Gn 2.61; Northcote, 1979), so further studies focussed on physiology of its resprouting, water use and water-use efficiency at a similar site near Kalannie. Young E. kochii trees were well equipped with large numbers of meristematic foci and adequate root starch reserves to endure repeated shoot removal. The cutting season and interval between cuts were then demonstrated to have a strong influence on productivity, since first-year coppice growth was slow and root systems appeared to cease in secondary growth during the first 1.5—2.5 years after cutting. After decapitation, trees altered their physiology to promote rapid replacement of shoots. Compared to uncut trees, leaves of coppices were formed with a low carbon content per unit area, and showed high stomatal conductance accompanied by high leaf photosynthetic rates. Whole-plant water use efficiency of coppiced trees was unusually high due to their fast relative growth rates associated with preferential investments of photosynthates into regenerating canopies rather than roots. Despite relatively small leaf areas on coppice shoots over the two years following decapitation, high leaf transpiration rates resulted in coppices using water at rates far in excess of that falling as rain on the tree belt area. Water budgets showed that 20 % of the study paddock would have been needed as 0—2 year coppices in 5 m wide twin-row belts in order to maintain hydrological balance over the study period. Maximum water use occurred where uncut trees were accessing a fresh perched aquifer, but where this was not present water budgets still showed transpiration of uncut trees occurring at rates equivalent to 3—4 times rainfall incident on the tree belt canopy. In this scenario, only 10 % of the paddock surface would have been required under 5 m wide tree belts to restore hydrological balance, but competition losses in adjacent pasture would have been greater

Coppicing -- Western Australia

Tree crops -- Western Australia

Eucalyptus -- Western Australia

Eucalyptus oil -- Western Australia

Tree water use

Alley farming

Agroforestry

Oil mallee

Silviculture

Hydrology

Starch

Carbon isotype discrimination

Coppice

Resprouting

Short rotation forestry

Lignotuber

Gas exchange

Water use efficiency

Effet de la variabilité intra et interspécifique du bois sur les procédés de traitement thermique / Effect of the intra and interspecific variability of wood on heat modification processes

Hamada, Joël

16 November 2016

Dans le contexte du développement durable qui a vu l’introduction de la directive produits biocides BPD 98/8/CE, l’étude des méthodes innovantes de préservation du bois comme le traitement thermique revêt une importance prépondérante. Le traitement thermique du bois permet d’améliorer ses propriétés de résistance biologique, de stabilité dimensionnelle ainsi que son aspect esthétique, sans ajout de produit chimique. Les études actuelles sur la problématique de la qualité du bois traité thermiquement se focalisent sur les caractéristiques finales du bois déjà traité, l’influence des conditions de traitement ou encore l’effet essence. Les propriétés intrinsèques du bois avant le traitement ne sont pas encore prises en compte. Les propriétés du bois telles que la densité ou la composition chimique étant variables principalement sous l’effet de l’activité humaine comme la sylviculture, l’objectif de cette thèse était d’évaluer l’impact de cette variabilité chez le chêne sessile (Quercus petraea Liebll.) et le sapin (Abies alba Mill) sur leur modification par voie thermique. Un scanner et un micro-densitomètre à rayons X ont été utilisés pour caractériser la variation de la densité des échantillons de planches et des cernes de croissance provenant des arbres étudiés. Des traitements thermiques ont été réalisés dans un four pilote à conduction sous vide de type macro-thermobalance et un analyseur thermogravimétrique (ATG). Des analyses chimiques ont été également réalisées. Les résultats montrent qu’en prenant la perte de masse due à la dégradation thermique du bois comme réponse, les types de tissus du bois et la composition chimique influencent sa thermo-dégradation. Que ce soit chez Quercus petraea ou chez Abies alba, le bois de printemps était plus sensible au traitement thermique que son voisin de bois d’été. De plus, les portions radiales du tronc, du bois juvénile à l’aubier en passant par le bois mature, se dégradaient suivant des cinétiques différentes. En conclusion, la variation de la microstructure et la composition chimique de ces bois influencent leur cinétique globale de thermo-dégradation. La sylviculture impacte cette différence intraspécifique de cinétique de dégradation à l’échelle intra- et interarbre. En effet, dans le cas du sapin pectiné, une gestion très dynamique des forêts dans le but de stimuler la croissance rapide des arbres qui produisent de gros bois contenant des cernes très larges, est source de variation dans la structure anatomique et la composition chimique à l’intérieur des arbres en comparaison aux petits bois à croissance lente plus homogènes. Toutes ces analyses ont pour objectif final de comprendre le lien entre les propriétés initiales du bois et les modifications thermiques intervenant au cours du traitement afin d’apporter une information utile aux industriels lors du choix des pièces de bois destinées au traitement thermique en vue d’une amélioration de la qualité du bois traité thermiquement / In the context of sustainable development which has seen the introduction of the biocides directive BPD 98/8/CE in the EU, innovative wood preservation practices such as Heat Treatment (HT) become relevant. Wood HT, also termed wood thermal modification, is a physical modification technology by which wood is heated at around 200 °C in an inert atmosphere. The main purpose of the treatment is to improve the biological durability and dimensional stability of wood. Current studies on thermally modified wood (TMW) quality are focusing on treated material, on treatment conditions or on species effect on the end-product characteristics. Relatively little is known about the effect of intrinsic wood properties on its thermal modification. As wood properties vary especially under the influence of human activities through sylviculture, this thesis studied the effect of European oak and silver fir wood density and chemical composition on their thermal modification kinetic. An X rays computed tomography (CT) and densitometer were used to characterize wood samples. Boards were heat-treated by conduction under vacuum using a pilot furnace, whereas sawdust samples underwent thermo-gravimetric analysis under nitrogen. The analysis allowed finding intra- and interspecific variations, especially within growth rings and along radial direction (from pith to bark). Forest management impacted heat modification kinetic of the studied samples, especially in silver fir where fast grown wood was more sensitive to treatment. The finding will be used as additional information to the wood industry which will account for homogeneity of loadings destined to heat treatment

Analyse thermogravimétrique

Bois

Cerne

Chêne sessile

Composition chimique

Croissance

Densité

Masse volumique

Sapin

Scanner à rayons X

Sylviculture

Traitement thermique

Variabilité

Chemical composition

Density

Fir

Growth

Heat treatment

Juvenile wood

Oak

Ring

Silviculture

Thermo-Gravimetric analysis

Variability

Wood

X-Rays CT

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