苌姗姗,胡进波,赵广杰. 2011a. 不同干燥预处理对杨木应拉木孔隙结构的影响. 北京林业大学学报,33 (2):91-95. (Chang S S,Hu J B,Zhao G J. 2011a. Effects of different drying pretreatments on pore structure of poplar tension wood. Journal of Beijing Forestry University, 33(2):91-95.[in Chinese]) 苌姗姗,胡进波,Clair B,等. 2011b. 氮气吸附法表征杨木应拉木的孔隙结构. 林业科学,47 (10):134-140. (Chang S S,Hu J B,Clair B,et al. 2011b. Pore structure characterization of poplar tension wood by nitrogen adsorption-desorption method. Scientia Silvae Sinicae, 47(10):134-140.[in Chinese]) 李 坚. 1995. 木材科学. 哈尔滨:东北林业大学出版社. (Li J. 1995. Wood science. Harbin:Northeast Forestry University Press.[in Chinese]) 刘盛全,江泽慧. 1996. 刺楸木材应拉木材性研究. 林业科学,32(5):470-475. (Liu S Q,Jiang Z H. 1996. Study on the properties of tension wood in Kalopanax septemlobus (Thunb.) Koidz. Scientia Silvae Sinicae, 32(5):470-475.[in Chinese]) 刘一星,赵广杰. 2012. 木材学. 2版. 北京:中国林业出版社,143-148. (Liu Y X,Zhao G J. 2012. Wood science. 2ed. Beijing:China Forestry Publishing House, 143-148.[in Chinese]) 谭 维. 2012. 木材的宏观和微观识别. 黑龙江科技信息,(18):225. (Tan W. 2012. Macroscopic and microscopic identification of wood. Heilongjiang Science and Technology Information, (18):225.[in Chinese]) 王 哲,王喜明. 2014. 木材多尺度孔隙结构及表征方法研究进展. 林业科学,50 (10):123-133. (Wang Z,Wang X M. 2014. Research progress of multi-scale pore structure and characterization methods of wood. Scientia Silvae Sinicae, 50(10):123-133.[in Chinese]) 赵广杰. 2002. 木材中的纳米尺度、纳米木材及木材-无机纳米复合材料. 北京林业大学学报,24 (5/6):204-207. (Zhao G J. 2002. Nano-dimensions in wood, nano-wood, wood and inorganic nano-composites. Journal of Beijing Forestry University, 24(5/6):204-207.[in Chinese]) Baba K,Park Y W,Kaku T,et al. 2009. Xyloglucan for generating tensile stress to bend tree stem. Molecular Plant, 2(5):893-903. Barnett J R,Jeronimidis G. 2003. Reaction wood//Barnett J R, Jeronimidis G. Wood quality and its biological basis. Blackwell Publishing,119-136. Bowling A J,Vaughn K C. 2008. Immunocytochemical characterization of tension wood:gelatinous fibers contain more than just cellulose. American Journal of Botany, 95(6):655-663. Chang S S. 2014. Study of macromolecular and structural modifications occurring during the building of the tension wood cell wall:a contribution to the understanding of the maturation stress generation in tree. PhD thesis, University Montpellier Ⅱ, Montpellier, France. Chang S S,Clair B,Ruelle J,et al. 2009. Mesoporosity as a new parameter for understanding tension stress generation in trees. Journal of Experimental Botany, 60 (11):3023-3030. Clair B,Alméras T,Pilate G,et al. 2011. Maturation stress generation in poplar tension wood studied by synchrotron radiation microdiffraction. Plant Physiology, 155:562-570. Clair B,Alméras T,Yamamoto H,et al. 2006. Mechanical state of native cellulose microfibrils in tension wood. Biophysical Journal, 91 (3):1128-1135. Clair B,Gril J,Di Renzo F,et al. 2008. Characterization of a gel in the cell wall to elucidate the paradoxical shrinkage of tension wood. Biomacromolecules, 9 (2):494-498. Clair B,Thibault B. 2001. Shrinkage of the gelatinous layer of poplar and beech tension wood. IAWA Journal, 22 (2):121-131. Clair B,Thibaut B,Sugiyama J. 2005. On the detachment of the gelatinous layer in tension wood fiber. Journal of Wood Science, 51(3):218-221. Fahlen J,Salmen L. 2003. Cross-sectional structure of the secondary wall of wood fibers as affected by processing.Journal of Materials Science, 38(1):119-126. Fang C H,Clair B,Gril J,et al. 2007. Transverse shrinkage in G-fibers as a function of cell wall layering and growth strain. Wood Science and Technology, 41 (8):65-671. Fisher J B,Stevenson J W. 1981. Occurrence of reaction wood in branches of dicotyledons and its role in tree architecture. Botanical Gazette, 142 (1):82-95. Fournier M,Alméras T,Clair B,et al. 2014. Biomechanical action and biological functions//Gardiner B,Barnett J,Saranpää P,et al. The biology of reaction wood. Springer Heidelberg, 139-169. Furuya N,Takahashi S,Miyazaki M. 1970. The chemical composition of gelatinous layer from the tension wood of Populus euroamericana. Journal of the Japanese Wood Research Society,16(1):26-30. Gardiner B,Barnett J,Saranpää P,Gril J. 2014. The biology of reaction wood. Springer Series in Wood Science, Springer-Verlag Berlin Heidelberg. Gierlinger N,Sapei L,Paris O. 2008. Insights into the chemical composition of Equisetum hyemale by high resolution Raman imaging. Planta,227(5):969-980. Gierlinger N,Schwanninger M. 2006. Chemical imaging of poplar wood cell walls by confocal Raman microscopy. Plant Physiol, 140 (4):1246-1254. Gorshkova T A,Gurjanov O P,Mikshina P V,et al. 2010. Specific type of secondary cell wall formed by plant fibers. Russian Journal of Plant Physiology, 57 (3):328-341. Gorzsás A,Stenlund H,Persson P,et al. 2011. Cell-specific chemotyping and multivariate imaging by combined FT-IR microspectroscopy and OPLS analysis reveals the chemical landscape of secondary xylem. The Plant Journal, 66(5):903-914. Goswami L,Dunlop J W,Jungnikl K,et al. 2008. Stress generation in the tension wood of poplar is based on the lateral swelling power of the G-layer. The Plant Journal, 56 (4):531-538. Horikawa Y,Clair B,Sugiyama J. 2009. Varietal difference in cellulose microfibril dimensions observed by infrared spectroscopy. Cellulose, 16 (1):1-8. Isebrands J G,Bensend D W. 1972. Incidence and structure of gelatinous fibers within rapid-growing eastern cottonwood. Wood and Fiber Science, 4 (2):61-71. Joseleau J P,Imai T,Kuroda K,et al. 2004. Detection in situ and characterization of lignin in the G-layer of tension wood fibres of Populus deltoids. Planta,219(2):338-345. Kaku T,Serada S,Bada K,et al. 2009. Proteomic analysis of the G-layer in poplar tension wood. Journal of Wood Science, 55 (4):250-257. Kim J S,Daniel G. 2012. Distribution of glucomannans and xylans in poplar xylem and their changes under tension stress. Planta,236(1):35-50. Lafarguette F,Leplé J C,Déjardin A,et al. 2004. Poplar genes encoding fasciclin-like arabinogalactan proteins are highly expressed in tension wood. New Phytologist,164(1):107-121. Lehringer C,Gierlinger N,Koch G. 2008. Topochemical investigation on tension wood fibres of Acer spp.,Fagus sylvatica L. and Quercus robur L. Holzforschung,62(3):255-263. Mellerowicz E J,Baucher M,Sundberg B,et al. 2001. Unraveling cell wall formation in the woody dicot stem. Plant Molecular Biology,47:239-274. Mellerowicz E J,Immerzeel P,Hayashi T. 2008. Botanical briefing xyloglucan:the molecular muscle of trees. Annals of Botany, 102 (5):659-665. Müller M,Burghammer M,Sugiyama J. 2006. Direct investigation of the structural properties of tension wood cellulose microfibrils using microbeam X-ray fibre diffraction. Holzforschung, 60 (5):474-479. Nishikubo N,Awano T,Banasiak A,et al. 2007. Xyloglucan endo-transglycosylase (XET) functions in gelatinous layers of tension wood fibers in poplar-a glimpse into the mechanism of the balancing act of trees. Plant and Cell Physiology, 48 (6):843-855. Norberg H,Meier H. 1966. Physical and chemical properties of the gelatinous layer in tension wood fiber of aspen (Populus tremula L.). Holzforschung, 20 (6):174-178. Onaka F. 1949. Studies of compression-and tension-wood.Mokuzai Kenkyu, 24 (3):1-88. Panshin A J,de Zeeuw C. 1980. Textbook of Wood Technology.4th ed. Mc Graw-Hill Book Co., New York. Pilate G,Chabbert B,Cathala B,et al. 2004. Lignification and tension wood. Comptes Rendus Biologies,327(9):889-901. Prodhan A,Ohtani J,Funada R,et al. 1995. Ultrastructural investigation of tension wood fibre in Fraxinus mandshurica Rupr. var. Japonica Maxim. Annals of Botany,75(3):311-317. Qiu D,Wilson I W,Gan S,et al. 2008. Gene expression in Eucalyptus branch wood with marked variation in cellulose microfibril orientation and lacking G-layers. New Phytologist, 179 (1):94-103. Rao R V,Dayal R,Sharma B. 1983. Studies on the nature and pattern of distribution of tension wood in Hevea brasiliensis Muell. Arg. (rubber wood). Indian Forester, 109 (5):286-291. Roussel J R,Clair B. 2015. Evidence of the late lignification of the G-layer in Simarouba tension wood, to assist understanding how non-G-layer species produce tensile stress. Tree Physiology, 35 (12):1366-1377. Ruelle J. 2006. Analyse de la diversité du bois de tension de 3 espèces d'angiospermes de forêt tropicale humide de Guyane Française. Thesis, Forest and wood science Université Antilles Guyane. Cayenne,210. Ruelle J,Beauchene J,Thibaut A,et al. 2007a. Comparison of physical and mechanical properties of tension and opposite wood from ten tropical rainforest trees from different species. Annals of Forest Science, 64 (5):503-510. Ruelle J,Clair B,Beauchene J,et al. 2006. Tension wood and opposite wood in 21 tropical rain forest species. 2. Comparison of some anatomical and ultrastructural criteria. IAWA Journal, 27 (4):341-376. Ruelle J,Yamamoto H,Thibaut B. 2007b. Growth stresses and cellulose structural parameters in tension and normal wood from three tropical rainforest angiosperms species. BioResources, 2 (2):235-251. Sachsse H. 1965. Untersuchungen uber eigenschaften und funktionsweise des zugholzes der laubbaume. Schriftenreihe der Forstlichen Fakultat der Universitat Gottingen, 35. Scurfield G. 1972. Histochemistry of reaction wood cell walls in two species of Eucalyptus and in Triatania conferta R. BR.American Journal of Botany,20(1):9-26. Scurfield G,Wardrop A B. 1963. The nature of reaction wood. VⅡ. Lignification in reaction wood. Australian Journal of Botany,11(2):107-116. Thibaut B,Gril J,Fournier M. 2001. Mechanics of wood and trees:some new highlights for an old story. Comptes Rendus de l'Academie des Sciences Series ⅡB-Mechanics,329(9):701-706. Timell T E. 1967. Recent progress in the chemistry of wood hemicelluloses. Wood Science and Technology,1(1):45-70. Timell T E. 1986. Compression wood in gymnosperms. V.I.Bibliography, historical background, determination, structure, chemistry, topochemistry, physical properties, origins and formation of compression wood. Springer, Heidelberg. Toghraie N D,Parsapajouh H,Ebrahimzadeh B,et al. 2006. Tension wood in eucalypt trees.Journal of Science (University of Tehran), 32 (1):13-22. Wardrop A B. 1964. The reaction anatomy of arborescent angiosperms//Zimmermann M H. The formation of wood in forest tree. Academic, New York, 405-456. Wardrop A B,Dadswell H E. 1948. The nature of reaction wood.1.The structure and properties of tension wood fibres. Australian Journal of Scientific Research Series B-Biological Science, 1(1):3-16. Wardrop A B,Dadswell H E. 1955. The nature of reaction wood. IV. Variations in cell wall organization of tension wood fibres. Australian Journal of Botany, 3(2):177-189. Washusen R,Evans R. 2001. The association between cellulose crystallite width and tension wood occurrence in Eucalyptus globulus. IAWA Journal, 22 (3):235-243. Washusen R,Evans R,Southerton S. 2005. A study of Eucalyptus grandis and Eucalyptus globulus branch wood microstructure. IAWA Journal, 26 (2):203-210. Yoshida M,Ohta H,Yamamoto H,et al. 2002. Tensile growth stress and lignin distribution in the cell walls of yellow poplar,Liriodendron tulipifera Linn. Trees, 16 (7):457-464. |