https://orcid.org/0000-0001-8807-5370
References
- Awan AR, Chughtai MI, Ashraf MY, Mahmood K, Rizwan M, Akhtar M, Khan RA. 2012. Comparison for physico-mechanical properties of farm-grown Eucalyptus camaldulensis Dehn. with conventional timbers. Pak J Bot 44:2067–2070.
- Bamber RK. 1985. The wood anatomy of eucalyptus and papermaking. Appita. 38:210–216.
- Bello AA, Jimoh AA. 2018. Some physical and mechanical properties of African birch (Anogeissus leiocarpus) timber. J Appl Sci Environ Manag. 22:79–84. doi:10.4314/jasem.v22i1.14.
- Bowyer JL, Shmulsky R, Haygreen JG. 2003. Forest products and wood science: an introduction. 2121 State Avenue, Ames, Iowa, USA: Blackwell Publishing.
- Çavuş V, Şahin S, Esteves B, Ayata U. 2019. Determination of thermal conductivity properties in some wood species obtained from Turkey. BioResources 14:6709–6715. doi:10.15376/biores.14.3.6709-6715.
- Chehreh F, Farahani MM. 2015. Surface droplet contact angle and colour characteristics of Eastern cottonwood treated with nano-copper oxide and exposed to natural weathering. Int Wood Prod J. 6:69–71. doi:10.1179/2042645314Y.0000000092.
- Ethington RL, Hilbrand HC. 1966. Anisotropy in wood. York, PA: ASTM International.
- Faouel J, Mzali F, Jemni A, Nasrallah SB. 2012. Thermal conductivity and thermal diffusivity measurements of wood in the three anatomic directions using the transient hot-bridge method. STRPM. 3(3):229–237; doi:10.1615/SpecialTopicsRevPorousMedia.v3.i3.50.
- Fu ZZ, Gao X, Liu H, Zhou F. 2019. Changes of water related properties in radiata pine wood owing to heat treatment. Constr Build Mater 227:116692. doi:10.1016/j.conbuildmat.2019.116692.
- Gustavsson M, Gustavsson JS, Gustafsson SE, Halldahl L. 2000. Recent developments and applications of the hot disc thermal constants analyser for measuring thermal transport properties of solids. High Temp High Press. 32:47–52. doi:10.1068/htwu259.
- Guyot A, Ostergaard KT, Lenkopane M, Fan J, Lockington DA. 2013. Using electrical resistivity tomography to differentiate sapwood from heartwood: application to conifers. Tree Physiol 33:187–194. doi:10.1093/treephys/tps128.
- Hazenberg G, Yang KC. 1991. Sapwood/heartwood width relationships with tree age in balsam fir. IAWA J. 12:95–99. doi:10.1163/22941932-90001210.
- Hillis WE. 1987. Chemical features. heartwood and tree exudates. Berlin: Springer.
- Horáček P, Fajstavr M, Stojanović M. 2018. The variability of wood density and compression strength of Norway spruce (Picea abies/L. /Karst.) within the stem. Beskydy. 10:17–26. doi:10.11118/beskyd201710010017.
- Kajita H, Skaar C. 1992. Wettability of the surfaces of some American softwoods species. JWRS. 38:516–521.
- Khazaei J. 2008. Water absorption characteristics of three wood svarieties. Cercetări Agronomice în Moldova. 41(2):134.
- Kollmann FP, Côté WF. 1984. Solid wood. principles of wood science and technology. Reprint Springer-Verlag, Tokyo, 1, 180.
- Kutz M. 2012. Handbook of environmental degradation of materials, 3rd ed. New York: Elsevier.
- Lagüela S, Bison P, Peron F, Romagnoni P. 2015. Thermal conductivity measurements on wood materials with transient plane source technique. Thermochim Acta. 600:45–51. doi:10.1016/j.tca.2014.11.021.
- Mantanis GI, Young RA. 1997. Wetting of wood. Wood Sci Technol 31:339–353. doi:10.1007/BF01159153.
- Priadi T, Sholihah M, Karlinasari L. 2019. Water absorption and dimensional stability of heat-treated fast-growing hardwoods. J Korean Wood Sci Technol. 47:567–578. doi:10.5658/WOOD.2019.47.5.567.
- Rice RW, Shepard R. 2004. The thermal conductivity of plantation grown white pine (Pinus strobus) and red pine (Pinus resinosa) at two moisture content levels. For Prod J. 54:92–94.
- Rowell RM. 2005. Handbook of wood chemistry and wood composites. Madison: CRC Press.
- Sandberg K. 2008. Degradation of Norway spruce (Picea abies) heartwood and sapwood during 5.5 years’ above-ground exposure. Wood Mater Sci Eng. 3:83–93. doi:10.1080/17480270902774886.
- Steinhagen HP. 1977. Thermal conductive properties of wood, green or dry, from-40 to+ 100 C: a literature review. USDA Forest Service General Technical Report (FPL-9), Wisconsin.
- Suleiman BM, Larfeldt J, Leckner B, Gustavsson M. 1999. Thermal conductivity and diffusivity of wood. Wood Sci Technol. 33:465–473. doi:10.1007/s002260050130.
- Sunny PP, Dutt B, Sharma KR, Dhiman B, Sumthane YY. 2019. Wood variation in physico-mechanical properties of Dalbergia sissoo Roxb. Ex DC. From local markets of Himachal Pradesh. J Trop Agric. 57:17–26.
- TenWolde A, McNatt JD, Krahn L. 1988. Thermal properties of wood and wood panel products for use in buildings (No. DOE/OR/21697-1). Forest Service, Madison, WI (USA). Forest Products Lab.
- Tripathi S, Bhoru YU. 2014. Changes in dimensional stability of Pinus roxburghii sarg. and Mangifera indica L. woods after rectification. Int Wood Prod J. 5:179–185. doi:10.1179/2042645314Y.0000000062.
- Tsoumis G. 1991. Science and technology of wood: structure, properties, utilization (Vol. 115). New York: Van Nostrand Reinhold.
- Weigenand O, Militz H, Tingaut P, Sebe G, deJeso B, Mai C. 2007. Penetration of amino-silicone micro-and macro-emulsions into Scots pine sapwood and the effect on water-related properties. 51–59.
- Wiedenhoeft AC, Miller RB. 2005. Structure and function of wood. In: Rowell RM, Rowell RM, editor. Handbook of wood chemistry and wood composites. Medison, WI: CRC Press; p. 9–33.
- Williams RS. 2005. Weathering of wood, chapter 7. In: Rowell RM, editor. Handbook of wood chemistry and wood composites. New York: CRC Press; p. 139–185.
- Young RA. 1976. Wettability of wood pulp fibers. Wood Fiber Sci 8:120–128.
- Yu ZT, Xu X, Fan LW, Hu YC, Cen KF. 2011. Experimental measurements of thermal conductivity of wood species in China: effects of density, temperature, and moisture content. For Prod J. 61:130–135. doi:10.13073/0015-7473-61.2.130.