[1]王涛.干旱区主要陆表过程与人类活动和气候变化研究进展[J].中国沙漠,2007,27(5):711-718. [2]王涛,赵哈林,肖洪浪.中国沙漠化研究进展[J].中国沙漠,1999,19(1):209-311. [3]李吉跃.油松侧柏抗旱能力初探[J].北京林业大学学报,1988,10(2):23-30. [4]李吉跃.P-V技术在油松侧柏苗木抗旱特性研究中的应用[J].北京林业大学学报,1989,11(1):3-11. [5]李吉跃.太行山主要造林树种抗旱特性的研究(Ⅰ)~(Ⅵ)[J].北京林业大学学报,1991,增刊(1-2):1-24,230-280. [6]李吉跃,张建国,姜金璞.北方主要造林树种耐旱机理及其分类模型的研究(Ⅰ)[J].北京林业大学学报,1993,15(3):1-9. [7]张建国,李吉跃,姜金璞.北京西山区人工林水分参数研究(Ⅰ)[J].北京林业大学学报,1994,16(1):1-12. [8]张建国,李吉跃,姜金璞.北京西山区人工林水分参数研究(Ⅱ)[J].北京林业大学学报,1994,16(2):1-9. [9]龚吉蕊,张立新,赵爱芬,等.油蒿抗旱生理生化特性研究初报[J].中国沙漠,2002,22(4):387-392. [10]张道远,尹林克,潘伯荣.柽柳属植物抗旱性能研究及其应用潜力评价[J].中国沙漠,2003,23(3): 252-56. [11]何明珠,王辉,陈智平.荒漠植物持水力研究[J].中国沙漠,2006,26(3):403-408. [12]俞理飞,朱守谦,叶镜中.喀斯特不同种组的耐旱适应性[J].南京林业大学学报,2002,26(1):19-22. [13]李吉跃,张建国,姜金璞.侧柏种源耐旱特性及其机理研究[J].林业科学,1997,33(4):1-13. [14]李吉跃.植物耐旱性及其机理[J].北京林业大学学报,1991,13(3):92-100. [15]Tyree M T,Ewers F W.The hydraulic architecture of tree and other woody plants[J].New Phytol,1991,119:345-360. [16]Zimmermann M H.Hydraulic architecture of some diffuse-porous trees[J].Can J Bot,1978,56:2286-2295. [17]潘瑞炽.植物生理学(第四版)[M].北京:高等教育出版社,2002:22-23. [18]Zimmermann,M H.Xylem Structure and the Ascent of Sap[J].Springer-Verlag,Berlin,1983. [19]Tyree M T,Dixon M A.Water-stress induced cavitation and embolism in some woody-plants[J].Physiol Plant,1986,66:397-400. [20]Scholander P F.The rise of sap in lianas[M]//Thimann K V (Eds).The Physiology of Forest Trees.New York:Ronald Press,1958:3-17. [21]Tyree M T,Dixon M A.Cavitation events in Thuja occidentalis L. ultrasonic acoustic emissions from sapwood can be measured[J].Plant Physiol,1983,72:1094-1099. [22]Milburn J A.Cavitation in Ricinus by acoustic detection: induction in excised leaves by various factors[J].Planta,1973,110:253-265. [23]Pickard W F.The ascent of sap in plants[J].Prog Biophys Mol Biol,1981,37:181-229. [24]Lewis A M.A test of the air-seeding hypothesis using sphagnum hyalocysts[J].Plant Physiol,1988,87:577-582. [25]Jarmila Pittermann,John S Sperry.Analysis of freeze-thaw embolism in Conifers.The interaction between cavitation pressure and tracheid size[J].Plant Physiology,2006,140:374-382. [26]Alfen N K V,Turner N C.Susceptbility in alfalfa stem conductance induced by Corynebacterium insideiosum toxin[J].Plant Physiol,1975,55:559-561. [27]Alfen N K V,Turner N C.Susceptbility of plant to vascular disruption by macromolecules[J].Plant Physiol,1979,63:1072-1075. [28]Tyree M T,Sperry J S.Vulnerability of xylem to cavitation and embolism[J].Ann Rev Plants Phys Mol Bio,1989,40:19-38. [29]Tyree M T,Dixon M A.Ultrasonic acoustic emissions from the sapwood of Cedar and Hemlock[J].Plant Physiol,1984,75:988-992. [30]Tyree M T,Dixon M A.Ultrasonic acoustic emissions from the sapwood of Thuja occidentalis measured inside a Pressure Bomb[J].Plant Physiol,1984,74:1046-1049. [31]Sperry J S,Donelly J R,Tyree M T.A method for measuring hydraulic conductivity and embolism in xylem[J].Plant Physiol,1988,11:35-40. [32]李吉跃,翟洪波.木本植物水力结构与抗旱性[J].应用生态学报,2000,11(2):301-305. [33]Salleo S,Lo Gullo M A.Difference aspects of cavitation resistance in Ceratonia siliqua, a drought-avoiding Mediterranean tree[J].Ann Bot,1989,64:325-336. [34]Jones H G,Sutherland R A.Stomatal control of xylem embolism[J].Plant,Cell and Environment,1991,14:607-612. [35]张硕新,申卫军,张远迎.几个抗旱树种木质部栓塞脆弱性的研究[J].西北林学院学报,1997,12(2):1-6. [36]Tyree M T,Yang S D.Water-storage capacity of Thuja, Tsuga and Acer stems measured by dehydration isotherms[J].Planta,1990,82:420-426. [37]Tyree M T,Snyderman D A.Water relations and hydraulic architecture of a tropical tree (Schefflera morototoni)[J].Plant Physiol,1991,96:1105-1113. [38]Tognetti R,Michelozzi M,Alessio G.Geographical variation in water relations, hydraulic architecture and terpene composition of Aleppo pine seedlings from Italian provenances[J].Tree Physiology,1997,17:241-250. [39]Martínez-Vilalta J.Drought-induced mortality and hydraulic architecture in pine population of the Iberian Peninsula[J].Forest Ecology and Management,2002,161:247-256. [40]申卫军.木本植物木质部空穴和栓塞化研究(综述)[J].热带亚热带植物学报,1999,7(3):257-266. [41]安锋,兰国玉,赵平娟.木质部空穴和栓塞化对植物的影响[J].热带农业科学,2004,24(6):53-67. [42]张硕新,Richter H.浆果紫杉木质部栓塞修复恢复情况的研究[J].西北林学院学报,1996,11(1):5-8. [43]张硕新,申卫军,张远迎,等.几个耐旱树种木质部栓塞脆弱性的研究[J].西北林学院学报,1997,12(2):1-6. [44]张硕新,Richter H.Seasonal variation hydraulic conductivity in twigs of woody plants[J].西北林学院学报,1996,11(3):1-9. [45]申卫军,彭少麟,张硕新.三个耐旱树种木质部栓塞化的脆弱性及其恢复能力[J].生态学杂志,2000,19(6):1-6. [46]申卫军,张硕新.几种木本植物木质部栓塞的日变化[J].西北林学院学报,1999,14(1):22-27. [46]申卫军,张硕新.几种木本植物木质部栓塞的季节变化[J].西北林学院学报,1999,14(1):28-32. [48]张硕新,申卫军,张远迎.六种木本植物木质部栓塞化生理生态效应的研究[J].生态学报,2000,20(5):788-794. [49]谢东锋,马履一,王华田.七种造林树种木质部栓塞脆弱性研究[J].浙江林学院学报,2004,21(2):138-143. [50]李晶,高玉葆,郑志荣,等.内蒙古高原不同生境三种锦鸡儿属植物的水力结构特征及其对环境因子的响应[J].生态学报,2007,27(3):837-845. [51]翟洪波,李吉跃.应用热扩散技术对油松栓皮栎比导率的研究[J].林业科学,2006,42(8):14-18. [52]翟洪波,李吉跃.油松、侧柏苗木水力结构特征的对比研究[J].生态学报,2002,22(11):1890-1895. [53]李吉跃,翟洪波.树木水力结构特征昼夜变化规律[J].北京林业大学学报,2002,24(4):39-44. [54]翟洪波,姜金璞.干旱胁迫对油松侧柏苗木水力结构特征的影响[J].北京林业大学学报,2002,24(5):45-49. [55]翟洪波,李吉跃.元宝枫苗木的水力结构特征[J].应用生态学报,2003,14(9):1411-1415 . [56]翟洪波,李吉跃.油松的水力结构特征[J].林业科学,2003,39(2):14-20. [57]刘晓燕,李吉跃,翟洪波,等.从树木水力结构特征探讨植物耐旱性[J].北京林业大学学报,2003,25(3):48-54. [58]樊大勇,谢宗强.木质部导管空穴化研究中的几个热点问题[J].植物生态学报,2004,28(1):126-132. [59]Jaekson R B,Sperry J S,Dawson T E.Root water uptake and transport:using physiological processes in global predictions[J].Trends in Plant Science,2000(5):482-488. |