[1] JIN Y G. Botany[M].Beijing: Science Press,2010:46.
[2] ZHANG Z, MA J, JI Z, et al. Comparison of anatomy and composition distribution between normal and compression wood of Pinus bungeana Zucc. revealed by microscopic imaging techniques [J]. Microscopy and Microanalysis, 2012, 18(6): 1459-1466.
[3] YEH T F, GOLDFARB B, CHANG H M, et al. Comparison of morphological and chemical properties between juvenile wood and compression wood of Loblolly pine [J]. Holzforschung, 2005, 59(6): 669-674.
[4] BURDON R D. Compression wood in Pinus radiata clones on four different sites [J]. New Zealand Journal of Forestry Science, 1975,5(2):152-164.
[5] KWON M, BEDGAR D L, PIASTUCH W, et al. Induced compression wood formation in Douglas fir (Pseudotsuga menziesii) in microgravity [J]. Phytochemistry, 2001, 57(6): 847-857.
[6] YAMASHITA S, YOSHIDA M, YAMAOTO H. Relationship between development of compression wood and gene expression [J]. Plant Science, 2009, 176(6): 729-735.
[7] DONALDSON L A, GRACE J, DOWNES G M. Within-tree variation in anatomical properties of compression wood in radiata pine [J]. IAWA Journal, 2004, 25(3): 253-272.
[8] YUMOTO M, ISHIDA S, FUKAZAWA K. Studies on the formation and structure of the compression wood cells induced by artificial inclination in young trees of Picea glauca:Ⅳ:gradation of the severity of compression wood tracheids [J]. Research Bulletins of the College Experiment Forests Hokkaido University, 1983, 40(2): 409-454.
[9] FRIML J, WISNIEWSKA J, BENKOVÁ E, et al. Lateral relocation of auxin efflux regulator PIN3 mediates tropism in Arabidopsis [J]. Nature, 2002, 415(6873): 806-809.
[10] MUDAY G K, DELONG A. Polar auxin transport: controlling where and how much [J]. Trends in Plant Science, 2001, 6(11): 535-542.
[11] TIMELL T E. Compression wood in Gymnosperms:3: ecology of compression wood formation, silviculture and compression wood, mechanism of compression wood action, compression wood in the lumber and pulp and paper industries, compression wood induced by the balsam woolly aphid, opposite wood [M]. New York:Springer-Verlag,1986.
[12] YAMAGUCHI K, SHIMAJI K, ITOH T. Simultaneous inhibition and induction of compression wood formation by morphactin in artificially inclined stems of Japanese larch (Larix leptolepis Gordon) [J]. Wood Science and Technology, 1983, 17(2): 81-89.
[13] SUNDBERG B, TUOMINEN H, LITTLE C H A. Effects of the indole-3-acetic acid (IAA) transport inhibitors N-1-naphthylphthalamic acid and morphactin on endogenous IAA dynamics in relation to compression wood formation in 1-year-old Pinus sylvestris (L.) shoots [J]. Plant Physiology, 1994, 106(2): 469-476.
[14] PHARIS R P, KUO C G. Physiology of gibberellins in conifers [J]. Canadian Journal of Forest Research, 1977,7(2): 299-325.
[15] PHARIS R, KUO C, GLENN J L. Gibberellins, a primary determinant in the expression of apical dominance, apical control and geotropic movement of conifer shoots [M]. Berlin: Springer-Verlag, 1972:441-448.
[16] WARDROP A B, DAVIES G W. The nature of reaction wood:VIII:the structure and differentiation of compression wood [J]. Australian Journal of Botany, 1964, 12(1): 24-38.
[17] LARSON P R. Auxin gradients and the regulation of cambial activity [M]. New York: Ronald Press, 1962: 97-117.
[18] LARSON P R. A biological approach to wood quality [J]. Tappi, 1962, 45(6): 443-448.
[19] 金银跟.植物学[M].北京:科学出版社,2010:46.
[20] JUNTTILA O. Gibberellins and the regulation of shoot elongation in woody plants [M]. New York: Springer-verlag,1991:199-210.
[21] WANG Q, LITTLE C H A, ODÉN P C. Effect of laterally applied gibberellin A4/7 on cambial growth and the level of indole-3-acetic acid in Pinus sylvestris shoots [J]. Physiologia Plantarum, 1995, 95(2): 187-194.
[22] LITTLE C H A, MACDONALD J E. Effects of exogenous gibberellin and auxin on shoot elongation and vegetative bud development in seedlings of Pinus sylvestris and Picea glauca [J]. Tree Physiology, 2003, 23(2): 73-83.
[23] PHARIS R P, YEH F C, DANCIK B P. Superior growth potential in trees: what is its basis, and can it be tested for at an early age? [J]. Canadian Journal of Forest Research, 1991, 21(3): 368-374.
[24] LITTLE C H A, PHARIS R P. Hormonal control of radial and longitudinal growth in the tree stem [M]. San Diego: Academic Press,1995.
[25] MORITZ T, OLSEN J E. Comparison between high-resolution selected ion monitoring, selected reaction monitoring, and four-sector tandem mass spectrometry in quantitative analysis of gibberellins in milligram amounts of plant tissue [J]. Analytical Chemistry, 1995, 67(10): 1711-1716.
[26] ODANI K. The effects of indoleacetic acid and chilling on cambial activity of Pinus densiflora [J]. J Jap Soc, 1975, 57: 112-16.
[27] EWERS F W, ALONI R. Effects of applied auxin and gibberellin on phloem and xylem production in needle leaves of Pinus [J]. Botanical Gazette, 1985,146(4):466-471.
[28] YAMAMOTO F, KOZlOWSKI T T. Effect of ethrel on growth and stem anatomy of Pinus halepensis seedlings [J]. IAWA Bull, 1987, 8: 11-19.
[29] NORBERG P H, MEIER H. Physical and chemical properties of the gelatinous layer in tension wood fibers of aspen (Populus tremula L.) [J]. Holzforschung-International Journal of the Biology, Chemistry, Physics and Technology of Wood, 1966, 20(6): 174-178.
[30] BENTUM A L K, CÔTÉ Jr W A, DAY A C, et al. Distribution of lignin in normal and tension wood [J]. Wood Science and Technology, 1969, 3(3): 218-231.
[31] TIMELL T E. The chemical composition of tension wood[[J]. Svensk Papp Tidn, 1969, 72: 173-181.
[32] ARCHER R R. Growth stresses and strains in trees [M]. New York: Springer-Verlag,1987.
[33] TSAI C, CHEN S, CHIEN C, et al. Induction of compression wood in seedlings of Taiwan incense cedar (Calocedrus macrolepis var. formosana) during the mid-season growth pause [J]. Botanical Studies, 2010, 51(2):163-170.
[34] BJÖRKLUND S. Plant hormones in wood formation [M]. Umeå: Arkitektkopia,2007.
[35] PILLOW M Y, LUXFORD R F. Structure, occurrence, and properties of compression wood [R].Washington:United States Department of Agriculture, Economic Research Service, 1937.
[36] PEREM E. The effect of compressionwood on the mechanical properties of white spruce and red pine [J]. Forest Products Journal, 1960,10(13):22.