Stress-wave velocity of trees and dynamic Young’s modulus of logs of 4-year-old Eucalyptus camaldulensis trees selected for pulpwood production in Thailand

Soerianegara I, Lemmens HMJ (1994) Plant resources of South-East Asia 5, (1) Timber trees: major commercial timbers. Prosea, Bogor

Cossalter C, Pye-Smith C (2003) Fast-wood forestry: myths and realities. Center for International Forestry Research, Bogor

Luangviriyasaeng V (2003) Eucalyptus planting in Thailand. In: Turnbull J (ed) Eucalyptus in Asia. Proceedings of the International Symposium, pp 28–31

Raymond CA (1991) Eucalyptus camaldulensis -a breeding for Thailand ACIAR Project 8808. CSIRO-Division of Forestry, Hobart

Eldridge K (1995) Breeding plan for Eucalyptus camaldulensis in Thailand. CSIRO-Division of Forestry, Canberra

Pinyopusarerk K, Doran JC, Williams ER, Wasuwanich P (1996) Variation in growth of Eucalyptus camaldulensis provenances in Thailand. For Ecol Manag 87:63–73

Ona T, Sonoda T, Ito K, Shibata M, Tamai Y, Kojima Y, Ohshima J, Yokota S, Yoshizawa N (2001) Investigation of relationships between cell and pulp properties in Eucalyptus by examination of within-tree property variations. Wood Sci Technol 35:229–243

Veenin T, Fujita M, Nobuchi T, Siripatanadilok S (2005) Radial variations of anatomical characteristics and specific gravity in Eucalyptus camaldulensis clones. IAWA J 26:353–361

Inagaki T, Schwanninger M, Kato R, Kurata Y, Thanapase W, Puthson P, Tsuchikawa S (2012) Eucalyptus camaldulensis density and fiber length estimated by near-infrared spectroscopy. Wood Sci Technol 46:143–155

Ishiguri F, Iizuka K, Tanabe J, Wedatama S, Yokota S, Yoshizawa N (2012) Solid wood properties of Eucalyptus camaldulensis planted for pulpwood production in Thailand. Wood Fiber Sci 44:108–110

Sungtong T, Diloksumpun S (2011) Variations in physiological characteristics of different Eucalyptus camaldulensis Dehnh. half-sib families. Thai J For 30(3):1–13

Ishiguri F, Eizawa J, Saito Y, Iizuka K, Yokota S, Priadi D, Sumiasri N, Yoshizawa N (2007) Variation in the wood properties of Paraserianthes falcataria planted in Indonesia. IAWA J 28:339–348

Ishiguri F, Matsui R, Iizuka K, Yokota S, Yoshizawa N (2008) Prediction of the mechanical properties of lumber by stress-wave velocity and Pilodyn penetration of 36-year-old Japanese larch trees. Holz Roh Werkst 66:275–280

Ishiguri F, Wahyudi I, Takeuchi M, Takashima Y, Iizuka K, Yokota S, Yoshizawa N (2011) Wood properties of Pericopsis mooniana grown in a plantation in Indonesia. J Wood Sci 57:241–246

Blackburn D, Hamilton M, Harwood C, Innes T, Potts B, Williams D (2010) Stiffness and checking of Eucalyptus nitens sawn boards: genetic variation and potential for genetic improvement. Tree Gene Genome 6:757–765

Makino K, Ishiguri F, Wahyudi I, Takashima Y, Iizuka K, Yokota S, Yoshizawa N (2012) Wood properties of young Acacia mangium trees planted in Indonesia. For Prod J 62:102–106

Kojima M, Yamamoto H, Yoshida M, Ojio Y, Okumura K (2009) Maturation property of fast-growing hardwood plantation species: a view of fiber length. For Ecol Manag 257:15–22

Ilic J (2001) Relationship among the dynamic and static elastic properties of air-dry Eucalyptus delegatensis R. Baker. Holz Roh Werkst 59:169–175

Hirakawa Y, Yamashita K, Nakada R, Fujisawa Y (1997) The effects of S2 microfibril angles of latewood tracheids and densities on modulus of elasticity variations of sugi tree (Cryptomeria japonica) logs (in Japanese). Mokuzai Gakkaishi 43:717–724

Yamashita K, Hirakawa Y, Fujisawa Y, Nakada R (2000) Effects of microfibril angle and density on variation of modulus of elasticity of sugi (Cryptomeria japonica) logs among eighteen cultivars (in Japanese). Mokuzai Gakkaishi 45:510–522

Evans R, Ilic J (2001) Rapid prediction of wood stiffness from microfibril angle and density. Forest Prod J 51(3):53–57

Koizumi A, Takata K, Ueda K, Katayose T (1990) Radial growth and wood quality of plus trees of Japanese larch I: radial growth, density, and trunk modulus of elasticity of grafted clones (in Japanese). Mokuzai Gakkaishi 36:98–102

Ikeda K, Arima T (2000) Quality evaluation of standing trees by a stress-wave propagation method and its application II: evaluation of sugi stands and application to production of sugi (Cryptomeria japonica D. Don) structural square sawn timber (in Japanese). Mokuzai Gakkaishi 46:189–196

Ross RJ, McDonald KA, Green DW, Schad KC (1997) Relationship between log and lumber modulus of elasticity. Forest Prod J 47(2):89–92

Wang X, Ross RJ, McClellan M, Barbour RJ, Erikson JR, Forsman JW, McGinnis GD (2001) Nondestructive evaluation of standing trees with a stress wave method. Wood Fiber Sci 33:522–533

Iki T, Tamura A, Nishioka N, Abe M (2006) Longitudinal change of dynamic modulus of elasticity and quality evaluation by a non-destructive method in todomatsu (Abies sachalinensis) plus trees (in Japanese). Mokuzai Gakkaishi 52:344–351