Wood quality of Khaya senegalensis trees from a multi-stratified agroforestry system established in an open ombrophilous forest zone

References

• Abdelgaleil, S. A., Hashinaga, F. and Nakatani, M. (2005) Antifungal activity of limonoids from Khaya ivorensis. Pest Management Science, 61(2), 186–190.
   PubMed Web of Science ®Google Scholar
• ABNT (2003a) NBR 14660, Wood Sampling and Preparation for Analysis (Rio de Janeiro: ABNT).
   Google Scholar
• ABNT (2003b) NBR 14853, Wood Determination of Material Soluble in Ethanol-Toluene and Dichloromethane (Rio de Janeiro: ABNT).
   Google Scholar
• ABNT (2003c) NBR 7989, Cellulosic Pulp and Wood Determination of Acid-Insoluble Lignin (Rio de Janeiro: ABNT).
   Google Scholar
• ABNT (2003d) NBR 13999, Paper, Cardboard, Cellulose Pulp, and Wood - Determination of the Residue (Gray) After Incineration at 525 °C (Rio de Janeiro: ABNT).
   Google Scholar
• Ahvenainen, P. (2019) Anatomy and mechanical properties of woods used in electric guitars. IAWA Journal, 40(1), 106–1S6.
   Web of Science ®Google Scholar
• Alinoori, F., Moshiri, F., Sharafi, P. and Samali, B. (2020) Reinforcement methods for compression perpendicular to grain in top/bottom plates of light timber frames. Construction and Building Materials, 231, 116377.
   Web of Science ®Google Scholar
• Almeida, J. P. B., Aquino, V. B. M., Wolenski, A. R. V., Campos, C. I., Molina, J. C., Chahud, E., Lahr, F. A. R. and Christoforo, A. L. (2020) Analysis of relations between the moduli of elasticity in compression, tension, and static bending of hardwoods. BioResources, 15(2), 3278–3288.
   Web of Science ®Google Scholar
• Alvares, C. A., Stape, J. L., Sentelhas, P. C., Gonçalves, J. L. M. and Sparovek, G. (2014) Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift, 22(6), 711–728.
   Web of Science ®Google Scholar
• Alves, R. M., Chaves, S. F. S. and Bastos, A. J. R. (2020) Viability of the use of african mahogany with cupuassu tree in agroforestry system (AFS). Revista Árvore, 44, e4407.
   Web of Science ®Google Scholar
• Andrade, A. C. A., Silva, J. R. M., Moulin, J. C., Oliveira, M. B., Souza, M. T. and Lima, C. L. (2018) Quality of machined surfaces and specific cutting energy in wood of two African mahogany species. Scientia Forestalis, 46(120), 532–539.
   Web of Science ®Google Scholar
• Ansell, M. P. (2011) Wood—A 45th anniversary review of JMS papers. Part 1: The wood cell wall and mechanical properties. Journal of Materials Science, 46, 7357–7368.
   Google Scholar
• Appiah-Kubi, E., Kankam, C. K., Frimpong-Mensah, K. and Opuni-Frimpong, E. (2016) The bending strength and modulus of elasticity properties of plantation-grown Khaya ivorensis (African Mahogany) from Ghana. Journal of the Indian Academy of Wood Science, 13(1), 48–54.
   Web of Science ®Google Scholar
• Araújo, S. O., Vital, B. R., Oliveira, B., Carneiro, A. C. O., Lourenço, A. and Pereira, H. (2016) Physical and mechanical properties of heat treated wood from Aspidosperma populifolium, Dipteryx odorata and Mimosa scabrella. Maderas. Ciencia y Tecnología, 18(1), 143–156.
   Web of Science ®Google Scholar
• Arévalo, R. and Hernández, R. E. (2001) Influence of moisture sorption on swelling of Mahogany (Swietenia macrophylla King) wood. Holzforschung, 55, 590–594.
   Web of Science ®Google Scholar
• ASTM (2014) ASTM D 143, Standard Test Methods for Small Clear Specimens of Timber (West Conshohocken, PA: ASTM International).
   Google Scholar
• ASTM (2017) ASTM D 5536, Standard Practice for Sampling Forest Trees for Determination of Clear Wood Properties. (West Conshohocken, PA: ASTM International).
   Google Scholar
• Athomo, A. B. B., Anris, S. P. E., Tchiama, R. S., Santiago-Medina, F. J., Cabaret, T., Pizzi, A. and Charrier, B. (2018) Chemical composition of African mahogany (K. ivorensis A. Chev.) extractive and tannin structures of the bark by MALDI-TOF. Industrial Crops and Products, 113, 167–178.
   Web of Science ®Google Scholar
• Athomo, A. B. B., Anris, S. P. E., Tchiama, R. S., Pizzi, L. L. A. and Charrier, B. (2020) Chemical analysis and thermal stability of African mahogany (Khaya ivorensis A. Chev) condensed tannins. Holzforschung, 74(7), 683–701.
   Web of Science ®Google Scholar
• Bennett, B. C. (2016) The sound of trees: Wood selection in guitars and other chordophones. Economic Botany, 70(1), 49–63.
   Web of Science ®Google Scholar
• Bhat, K. M. and Priya, P. B. (2004) Influence of provenance variation on wood properties of teak from the western Ghat region in India. IAWA Journal, 25(3), 273–282.
   Web of Science ®Google Scholar
• Bradbury, G. J., Potts, B. M. and Beadle, C. L. (2011) Genetic and environmental variation in wood properties of Acacia melanoxylon. Annals of Forest Science, 68, 1363–1373.
   Web of Science ®Google Scholar
• Brennan, G. K. and Radomiljac, A. M. (1998) Preliminary observations on the utilization and wood properties of plantation teak (Tectona grandis) and African mahogany (Khaya senegalensis) grown near Kununurra, Western Australia. Australian Forestry, 61(2), 120–126.
   Google Scholar
• Burcham, D. C., Wong, J. Y., Ali, M. I. M., Abarrientos Junior, N. V., Fong, Y. K. and Schwarze, F. W. M. R. (2015) Characterization of host-fungus interactions among wood decay fungi associate with Khaya senegalensis (Desr.) A. Juss (Meliaceae) in Singapore. Forest Pathology, 45(6), 492–504.
   Web of Science ®Google Scholar
• Bush, D., Harwood, C. and Pinkard, E. (2018) Species for changing climates – Australian dryland forestry opportunities. Australian Forestry, 81(2), 102–115.
   Web of Science ®Google Scholar
• Câmara, A. P., Vidaurre, G. B., Oliveira, J. C. L., Picoli, E. A. T., Almeida, M. N. F., Roque, R. M., Tomazello Filho, M., Souza, H. J. P., Oliveira, T. R. and Campoe, O. C. (2020) Changes in hydraulic architecture across a water availability gradient for two contrasting commercial Eucalyptus clones. Forest Ecology and Management, 474, 118380.
   Web of Science ®Google Scholar
• Carneiro, J. S., Emmert, L., Sternadt, G. H., Mendes, J. C. and Almeida, G. F. (2009) Decay susceptibility of Amazon wood species from Brazil against white rot and brown rot decay fungi. Holzforschung, 63, 767–772.
   Web of Science ®Google Scholar
• Cavalli, A., Cibecchini, D., Togni, M. and Sousa, H. S. (2016) A review on the mechanical properties of aged wood and salvaged timber. Construction and Building Materials, 114, 681–687.
   Web of Science ®Google Scholar
• Chaikaew, P., Adeyemi, O., Hamilton, A. O. and Clifford, O. (2020) Spatial characteristics and economic value of threatened species (Khaya ivorensis). Scientific Reports, 10, 6266.
   PubMed Web of Science ®Google Scholar
• Charbonnier, F., Maire, G. L., Dreyer, E., Casanoves, F., Christina, M., Dauzat, J., Eitel, J. U. H., Vaast, P., Vierling, L. A. and Roupsard, O. (2013) Competition for light in heterogeneous canopies: Application of MAESTRA to a coffee (Coffea arabica L.) agroforestry system. Agricultural and Forest Meteorology, 181, 152–169.
   Web of Science ®Google Scholar
• Christoforo, A. L., Almeida, A. S., Lanini, T. L. S., Nogueira, R. S. and Lahr, F. A. R. (2019) Estimation of the characteristic value of wood strength. Engenharia Agrícola, 39(1), 127–132.
   Web of Science ®Google Scholar
• Christoforo, A. L., Aquino, V. B., Govone, J. S., Dias, A. M. P. G., Panzera, T. H. and Lahr, F. A. R. (2020) Alternative model to determine the characteristic strength value of wood in the compression parallel to the grain. Maderas. Ciencia y Tecnología, 22(3), 281–290.
   Web of Science ®Google Scholar
• Colares, C. J. G., Pastore, T. C. M., Coradin, V. T. R., Marques, L. F., Moreira, A. C. O., Alexandrino, G. L., Poppi, R. J. and Braga, J. W. B. (2016) Near infrared hyperspectral imaging and MCR-ALS applied for mapping chemical composition of the wood specie Swietenia macrophylla King (Mahogany) at microscopic level. Microchemical Journal, 124, 356–363.
   Web of Science ®Google Scholar
• Conrad, M. P. C., Smith, G. D. and Fernlund, G. (2003) Fracture of solid wood: A review of structure and properties at different length scales. Wood and Fiber Science, 35(4), 570–584.
   Web of Science ®Google Scholar
• Corrêa, F. L. O., Ramos, J. D., Gama-Rodrigues, A. C. and Müller, M. W. (2006) Produção de serapilheira em sistema agroflorestal multiestratificado no estado de Rondônia, Brasil. Ciência e Agrotecnologia, 30(6), 1099–1105.
   Google Scholar
• Curtis, R. O. and Marshall, D. D. (2000) Why quadratic mean diameter? Western Journal of Applied Forestry, 15(3), 137–139.
   Google Scholar
• Downes, G. M. and Drew, D. (2008) Climate and growth influences on wood formation and utilisation. Southern Forests, 70(2), 155–167.
   Web of Science ®Google Scholar
• Downes, G. M., Drew, D., Battaglia, M. and Schulze, D. (2009) Measuring and modelling stem growth and wood formation: An overview. Dendrochronologia, 27, 147–157.
   Web of Science ®Google Scholar
• Elaieb, M. T., Shel, F., Jalleli, M., Langbour, P. and Candelier, K. (2019) Physical properties of four ring-porous hardwood species: Influence of wood rays on tangential and radial wood shrinkage. Madera y Bosques, 25(2), e12521695.
   Web of Science ®Google Scholar
• ElAmin, E. E. and Mahmoud, A. E. (2015) Effect of air drying, solar-assisted air drying and sticker thickness on mahogany (Khaya senegalensis) wood. Forest Research, 4(3), 1000146.
   Google Scholar
• Ferreira, D. (2019) Sisvar: A computer analysis system to fixed effects split plot type designs. Revista Brasileira de Biometria, 37(4), 529–535.
   Google Scholar
• Ferreira, M. D., Melo, R. R., Tonini, H., Pimenta, A. S., Gatto, D. A., Beltrame, R. and Stangerlin, D. M. (2020) Physical–mechanical properties of wood from a eucalyptus clone planted in an integrated crop-livestock-forest system. International Wood Products Journal, 11(1), 12–19.
   Web of Science ®Google Scholar
• Fonweban, J., Mavrou, I., Gardiner, B. and Macdonald, E. (2013) Modelling the effect of spacing and site exposure on spiral grain angle on Sitka spruce (Picea sitchensis (Bong.) Carr.) in Northern Britain. Forestry, 86(3), 331–342.
   Web of Science ®Google Scholar
• França, T. S. F. A. (2014) Caracterização tecnológica das madeiras de duas espécies de mogno africano (Khaya ivorensis A. Chev. e Khaya senegalensis (Desr.) A. Juss. Master Thesis. Federal University of Espírito Santo.
   Google Scholar
• França, T. S. F. A., Arantes, M. D. C., Paes, J. B., Vidaurre, G. B., Oliveira, J. T. S. and Baraúna, E. E. P. (2015) Características anatômicas e propriedades físico-mecânicas das madeiras de duas espécies de mogno africano. Cerne, 21(4), 633–640.
   Google Scholar
• França, T. S. F. A., França, F. J. N., Arango, R. A., Woodward, B. M. and Arantes, M. D. C. (2016) Natural resistance of plantation grown African mahogany (Khaya ivorensis and Khaya senegalensis) from Brazil to wood-rot fungi and subterranean termites. International Biodeterioration & Biodegradation, 107, 88–91.
   Web of Science ®Google Scholar
• Freitas, T. P., Oliveira, J. T. S., Vidaurre, G. B. and Rodrigues, B. P. (2018) Environmental effect on chemical composition of Eucalyptus clones wood for pulp production. Cerne, 24(3), 219–224.
   Web of Science ®Google Scholar
• Fromm, J. (2012) Basic processes of wood formation. In J. Fromm (ed.), Cellular Aspects of Wood Formation (Heidelberg: Springer), pp. 3–15.
   Google Scholar
• Gérard, J., Guibal, D., Paradis, S. and Cerre, J. C. (2017) Tropical Timber Atlas: Technological Characteristics an Uses (Yokohama: ITTO).
   Google Scholar
• Gérard, J., Paradis, S. and Thibaut, B. (2019) Survey on the chemical composition of several tropical wood species. Bois et Forêts des Tropiques, 342, 79–91.
   Google Scholar
• Gibson, C. and Warren, A. (2016) Resource-sensitive global production networks: Reconfigured geographies of timber and acoustic guitar manufacturing. Economic Geography, 92(4), 430–454.
   Web of Science ®Google Scholar
• Gierlinger, N. and Wimmer, R. (2004) Radial distribution of heartwood extractives and lignin in mature European larch. Wood and Fiber Science, 36(3), 387–394.
   Web of Science ®Google Scholar
• Hein, P. R. G., Chaix, G., Clair, B., Brancheriau, L. and Gril, J. (2016) Spatial variation of wood density, stiffness and microfibril angle along Eucalyptus trunks grown under contrasting growth conditions. Trees, 30, 871–882.
   Web of Science ®Google Scholar
• Hein, P. R. G. and Lima, J. T. (2012) Relationships between microfibril angle, modulus of elasticity and compressive strength in Eucalyptus wood. Maderas. Ciencia y Tecnología, 14(3), 2012.
   Web of Science ®Google Scholar
• Hein, P. R. G. and Brancheriau, L. (2018) Comparison between three-point and four-point flexural tests to determine wood strength of Eucalyptus specimens. Maderas. Ciencia y Tecnología, 20(3), 333–342.
   Web of Science ®Google Scholar
• Hillis, W. E. (1971) Distribution, properties and formation of some wood extractives. Wood Science and Technology, 5, 272–289.
   Web of Science ®Google Scholar
• Jankowska, A., Drozdzek, M., Sarnowski, P. and Horodenski, J. (2017) Effect of extractives on the equilibrium moisture content and shrinkage of selected tropical wood species. BioResources, 12(1), 597–607.
   Web of Science ®Google Scholar
• Jahan, M. S., Rahman, M. M. and Ni, Y. (2021) Alternative initiatives for non-wood chemical pulping and integration with the biorefinery concept: A review. Biofuels, Bioproducts and Biorefining, 15(1), 100–118.
   Web of Science ®Google Scholar
• Khalid, S. A., Friedrichsen, G. M., Kharazmi, A., Theander, T. G., Olsen, C. E. and Christensen, S. B. (1998) Limonoids from Khaya senegalensis. Phytochemistry, 49(6), 1769–1772.
   PubMed Web of Science ®Google Scholar
• Kránitz, K., Sonderegger, W., Bues, C. T. and Niemz, P. (2016) Effects of aging on wood: A literature review. Wood Science and Technology, 50, 7–22.
   Web of Science ®Google Scholar
• Leonardon, M., Altaner, C. M., Vihermaa, L. and Jarvis, M. C. (2010) Wood shrinkage: Influence of anatomy, cell wall architecture, chemical composition and cambial age. European Journal of Wood and Wood Products, 68, 87–94.
   Web of Science ®Google Scholar
• Mania, P., Wróblewski, M., Wójciak, A., Roszyk, E. and Moliński, W. (2020) Hardness of densified wood in relation to changed chemical composition. Forests, 11(5), 506.
   Web of Science ®Google Scholar
• Mardsen, C., Martin-Chave, A., Cortet, J., Hedde, M. and Capowiez, Y. (2019) How agroforestry systems influence soil fauna and their functions – A review. Plant and Soil, 453, 29–44.
   Web of Science ®Google Scholar
• Mascarenhas, A. R. P., Sccoti, M. S. V., Melo, R. R., Corrêa, F. L. O., Souza, E. F. M., Andrade, R. A., Bergamin, A. C. and Müller, M. W. (2017) Atributos físicos e estoques de carbono do solo sob diferentes usos da terra em Rondônia, Amazônia Sul-Ocidental. Pesquisa Florestal Brasileira, 37(89), 19–27.
   Google Scholar
• Mohd-Jamil, A. W. and Khairul, M. (2017) Variations of mechanical properties in plantation timbers of jelutong (Dyera costulata) and Khaya (Khaya ivorensis) along the radial and vertical positions. Journal of Tropical Forest Science, 29(1), 114–120.
   Web of Science ®Google Scholar
• Moya, R. and Muñoz, F. (2010) Physical and mechanical properties of eight fast-growing plantation species in Costa Rica. Journal of Tropical Forest Science, 22(3), 317–328.
   Web of Science ®Google Scholar
• Moya, R., Bond, B. and Quesada, H. (2014) A review of heartwood properties of Tectona grandis trees from fast-growth plantations. Wood Science and Technology, 48, 411–433.
   Web of Science ®Google Scholar
• Nasir, V. and Cool, J. (2020) A review on wood machining: Characterization, optimization, and monitoring of the sawing process. Wood Material Science & Engineering, 15(1), 1–16.
   Web of Science ®Google Scholar
• Nordahlia, A. S., Hamdan, H. and Anwar, U. M. K. (2013) Wood properties of selected plantation species: Khaya ivorensis (african mahogany), Azadirachta excelsa (sentang), Endospermum malaccense (sesendok) and Acacia mangium. Timber Technology Bulletin, 51, 1–8.
   Google Scholar
• Olatunji, T. L., Odebunmi, C. A. and Adetunji, A. E. (2021) Biological activities of limonoids in the Genus Khaya (Meliaceae): A review. Future Journal of Pharmaceutical Sciences, 7(74), 1–16.
   Google Scholar
• Oliveira, X. M., Ribeiro, A., Ferraz Filho, A. C., Mayrinck, R. C., Lima, R. and Scolforo, J. R. S. (2018) Volume equations for Khaya ivorensis A. Chev. plantations in Brazil. Anais da Academia Brasileira de Ciências, 90(4), 3285–3298.
   PubMed Web of Science ®Google Scholar
• Pantera, A., Burgess, P. J., Losada, M. R., Moreno, G., López-Díaz, M. L., Corroyer, N., McAdam, J., Rosati, A., Papadopoulos, A. M., Graves, A., Rodríguez, A. R., Ferreiro-Domínguez, N., Fernández Lorenzo, J. L., González-Hernández, M. P., Papanastasis, V. P., Mantzanas, K., Lerberghe, P. V. and Malignier, N. (2018) Agroforestry for high value tree systems in Europe. Agroforestry Systems, 92, 945–959.
   Web of Science ®Google Scholar
• Poku, K., Wu, Q. and Vlosky, R. (2001) Wood properties and their variations within the tree stem of lesser-used species of tropical hardwood from Ghana. Wood and Fiber Science, 32(2), 284–291.
   Google Scholar
• Pretzsch, H. and Rais, A. (2016) Wood quality in complex forests versus even-aged monocultures: Review and perspectives. Wood Science and Technology, 50, 845–880.
   Web of Science ®Google Scholar
• Reis, J. C., Rodrigues, G. S., Barros, I., Rodrigues, R. A. R., Garret, R. D., Valentim, J. F., Kamoi, M. Y. T., Michetti, M., Wruck, F. J., Rodrigues-Filho, S., Pimentel, P. E. O. and Smukler, S. (2021) Integrated crop-livestock system: A sustainable land-use alternative for food production in the Brazilian Cerrado and Amazon. Journal of Cleaner Production, 283, 124580.
   Web of Science ®Google Scholar
• Rizanti, D. E., Darmawan, W., George, B., Merlin, A., Dumarcay, S., Chapuis, H., Gérardin, C., Gelhaye, E., Raharivelomanana, P., Sari, R. K., Syafii, W., Mohamed, R. and Gerardin, P. (2018) Comparison of teak wood properties according to forest management: Short versus long rotation. Annals of Forest Science, 75, 39.
   Web of Science ®Google Scholar
• Rocha, M. F. V., Veiga, T. R. L. A., Soares, B. C. D., Araújo, A. C. C., Carvalho, A. M. M. and Hein, P. R. H. (2019) Do the growing conditions of trees influence the wood properties? Floresta e Ambiente, 26(3), e20180353.
   Web of Science ®Google Scholar
• Rocha, S. M. G., Vidaurre, G. B., Pezzopane, J. E. M., Almeida, M. N. F., Carneiro, R. L., Campoe, O. C., Scolforo, H. F., Alvares, C. A., Neves, J. C. L., Xavier, A. C. and Figura, M. A. (2020) Influence of climatic variations on production, biomass and density of wood in Eucalyptus clones of different species. Forest Ecology and Management, 473(1), 118290.
   Google Scholar
• Ruffinatto, F., Crivellaro, A. and Wiedenhoeft, A. C. (2015) Review of macroscopic features for hardwood and softwood identification and a proposal for a new character list. IAWA Journal, 36(2), 208–241.
   Web of Science ®Google Scholar
• Sahin, C. K. and Onay, B. (2020) Alternative wood species for playgrounds wood from fruit trees. Wood Research, 65(1), 149–160.
   Web of Science ®Google Scholar
• Santana, M. A. E. and Okino, E. Y. A. (2007) Chemical composition of 36 Brazilian Amazon forest wood species. Holzforschung, 61, 469–477.
   Web of Science ®Google Scholar
• Santos, F. M., Terra, G., Chaer, G. M. and Monte, M. A. (2019) Modeling the height–diameter relationship and volume of young African mahoganies established in successional agroforestry systems in northeastern Brazil. New Forests, 50, 389–407.
   Web of Science ®Google Scholar
• Santos, L. H. O., Alexandre, F. S., Mendonza, Z. M. S. H., Souza, E. C., Borges, P. H. M., Mariano, R. R., Ruiz Diaz, L. M. G. and Nunes, C. A. (2020) Características químicas e físicas da madeira de mogno africano (Khaya ivorensis A. Chev.). Nativa, 8(3), 361–366.
   Google Scholar
• Sargent, R. (2019) Evaluating dimensional stability in solid wood: A review of current practice. Journal of Wood Science, 65, 36.
   Web of Science ®Google Scholar
• Schneeweiß, G. and Felber, S. (2013) Review on the bending strength of wood and influencing factors. American Journal of Materials Science, 3(3), 41–54.
   Google Scholar
• Sheng, J., Chen, J., Liu, C., Yang, Z., Yang, Y. and Lin, J. (2020) Changes in the chemical composition of young Chinese fir wood exposed to different soil temperature and water content. Cellulose, 27, 4067–4077.
   Web of Science ®Google Scholar
• Silva, J. G. M., Vidaurre, G. B., Arantes, M. D. C., Batista, D. C., Soranso, D. R. and Billo, D. F. (2016) Qualidade da Madeira de mogno africano para a produção de serrado. Scientia Forestalis, 44(109), 181–190.
   Google Scholar
• Silva, C. B. R., Santos Junior, J. A., Araújo, A. J. C., Sales, A., Siviero, M. A., Andrade, F. W. C., Castro, J. P., Latorraca, J. V. F. and Melo, L. E. L. (2020) Properties of juvenile wood of Schizolobium parahyba var. amazonicum (paricá) under different cropping systems. Agroforestry Systems, 94, 583–595.
   Web of Science ®Google Scholar
• Soranso, D. R., Vidaurre, G. B., Chagas, M. T., Oliveira, J. T. S., Silva, J. G. M. and Latorraca, J. V. F. (2018) Radial growth dynamics of Khaya ivorensis trees from experimental plantation. Revista Árvore, 42(2), e420207.
   Web of Science ®Google Scholar
• Sosanwo, O. A., Fawcett, A. H. and Apperley, D. (1995) 13C CP–MAS NMR spectra of tropical hardwoods. Polymer International, 36(3), 247–259.
   Web of Science ®Google Scholar
• Taylor, A. M., Baek, S. H., Jeong, M. K. and Nix, G. (2008) Wood shrinkage prediction using NIR spectroscopy. Wood Science and Technology, 40(2), 301–307.
   Google Scholar
• Tekpetey, S. L., Essien, C., Appiah-Kubi, E., Opuni-Frimpong, E. and Korang, J. (2016) Evaluation of the chemical composition and natural durability of natural and plantation grown African Mahogany Khaya ivorensis A. Chiev in Ghana. Journal of the Indian Academy of Wood Science, 13(2), 152–155.
   Web of Science ®Google Scholar
• Thomas, D., Henson, M., Joe, B., Boyton, S. and Dickson, R. (2009) Review of growth and wood quality of plantation-grown Eucalyptus dunnii Maiden. Australian Forestry, 72(1), 3–11.
   Web of Science ®Google Scholar
• Viani, R. A., Morais, J. P. G., Domene, F., Eugênio, E. R., Campana, M., Neto, E. L. and Oliveira, A. C. C. (2020) Bark-stripping of African mahogany trees (Khaya spp.) by cattle in silvipastoral systems in Brazil. Agroforestry Systems, 94, 2385–2390.
   Web of Science ®Google Scholar
• Vidaurre, G. B., Silva, J. G. M., Castro, M., Coelho, J. C. F., Brito, A. S. and Moulin, J. C. (2017) Relação da grã com algumas variáveis do crescimento e propriedades da madeira de Khaya ivorensis. Scientia Forestalis, 45(114), 249–259.
   Google Scholar
• Xue, Q., Sun, W., Fagerstedt, K., Guo, X., Dong, M., Wang, W. and Cao, H. (2018) Effects of wood rays on the shrinkage of wood during the drying process. BioResources, 13(3), 7086–7095.
   Web of Science ®Google Scholar
• You, R., Zhu, N., Deng, X., Wang, J. and Liu, F. (2021) Variation in wood physical properties and effects of climate for different geographic sources of Chinese fir in subtropical area of China. Scientific Reports, 11, 4664.
   PubMed Web of Science ®Google Scholar
• Zborowska, M., Stachowiak-Wence, A., Waliszewska, B. and Rądzyński, W. (2016) Colorimetric and FTIR ATR spectroscopy studies of degradative effects of ultraviolet light on the surface of exotic ipe (Tabebuia sp.) wood. Cellulose Chemistry and Technology, 50(1), 71–76.
   Web of Science ®Google Scholar
• Zobel, B. J. and Buijtenen, J. P. (2012) The properties of juvenile wood. In T. E. Timell (ed.), Wood Variation: Its Causes and Control (Heidelberg: Springer), pp. 90–93.
   Google Scholar