[1] Brodribb T J,Field T S.Leaf hydraulic evolution led a surge in leaf photosynthetic capacity during early angiosperm diversification[J].Ecology Letters,2010,13:175-183. [2] Hao G Y,Hoffmann W A,Scholz F G,et al.Stem and leaf hydraulics of congeneric tree species from adjacent tropical savanna and forest ecosystems[J].Oecologia,2008,155:405-415. [3] McDowell N,Pockman W T,Allen C D,et al.Mechanisms of plant survival and mortality during drought:why do some plants survive while others succumb to drought?[J].New Phytologist,2008,178:719-739. [4] Dixon H H,Joly J.On the ascent of sap[J].Philosophical Transactions of the Royal Society of London,Series B:Biological Sciences,1985,186:563-576. [5] Tyree M T,Zimmermann M H.Xylem Structure and the Ascent of Sap[M].Berlin,Germany:Springer,2002. [6] Pockman W T,Sperry J S.Vulnerability to xylem cavitation and the distribution of Sonoran desert vegetation[J].American Journal of Botany,2000,87:1287-1299. [7] Maherali H,Pockman W T,Jackson R B.Adaptive variation in the vulnerability of woody plants to xylem cavitation[J].Ecology,2004,85:2184-2199. [8] Markesteijn L,Poorter L.Seedling root morphology and biomass allocation of 62 tropical tree species in relation to drought-and shade-tolerance[J].Journal of Ecology,2009,97:311-325. [9] Pineda-García F,Paz H,Tinoco-Ojanguren.Morphological and physiological differentiation of seedlings between dry and wet habitats in a tropical dry forest[J].Plant,Cell and Environment,2011,34:1536-1547 [10] Zufferey V,Cochard H,Ameglio T,et al.Diurnal cycles of embolism formation and repair in petioles of grapevine(Vitis vinifera cv.Chasselas)[J].Journal Experimental Botany,2011,62:3885-3894. [11] Frederic L,Catherine P C,Chloé D,et al.Herbaceous angiosperms are not more vulnerable to drought-induced embolism than angiosperm trees[J].Plant Physiology,2016,172:661-667. [12] Fang X W,Turner N C,Xu D H,et al.Limits to the height growth of Caragana korshinskii resprouts[J].Tree Physiology,2013,33:275-284. [13] Markesteijn L,Poorter L,Paz H,et al.Ecological differentiation in xylem cavitation resistance is associated with stem and leaf structural traits[J].Plant,Cell and Environment,2011,34:137-148. [14] Pineda-García F,Paz H,Tinoco-Ojanguren.Morphological and physiological differentiation of seedlings between dry and wet habitats in a tropical dry forest[J].Plant,Cell and Environment,2011,34:1536-1547. [15] Hacke U G,Sperry J S,Wheeler J K,et al.Scaling of angiosperm xylem structure with safety and efficiency[J].Tree Physiology,2006,26:689-701. [16] Hacke U G,Jacobsen A L,Pratt R B.Xylem function of arid-land shrubs from California,USA:an ecological and evolutionary analysis[J].Plant,Cell and Environment,2009,32:1324-1333. [17] Wheeler J K,Sperry J S,Hacke U G,et al.Intervessel pitting and cavitation in woody Rosaceae and other vesselled plants:a basis for a safety versus efficiency trade-off in xylem transport[J].Plant,Cell and Environment,2005,28:800-812. [18] Choat B,Sack L,Holbrook N M.Diversity of hydraulic traits in nine Cordia species growing in tropical forests with contrasting precipitation[J].New Phytologist,2007,175:686-698. [19] Choat B,Jansen S.Global convergence in the vulnerability of forests to drought[J].Nature,2012,491:752-756. [20] Blackman C J,Brodribb T J,Jordan G J.Leaf hydraulic vulnerability influences species' bioclimatic limits in a diverse group of woody angiosperms[J].Oecologia,2012,168:1-10. [21] Blackman C J,Gleason S M,Chang Y,et al.Leaf hydraulic vulnerability to drought is linked to site water availability across a broad range of species and climates[J].Annals of Botany,2014,114:435-440. [22] Maherali H,Pockman W T,Jackson R B.Adaptive variation in the vulnerability of woody plants to xylem cavitation[J].Ecology,2004,85:2184-2199. [23] Nardini A,Luglio J.Leaf hydraulic capacity and drought vulnerability:possible trade-offs and correlations with climate across three major biomes[J].Functional Ecology,2014,28:810-818. [24] Nardini A,Pedà G,La R N.Trade-offs between leaf hydraulic capacity and drought vulnerability:morpho-anatomical bases,carbon costs and ecological consequences[J]. New Phytologist,2012,196:788-798. [25] Cai J,Tyree M T.The impact of vessel size on vulnerability curves:data and models for within-species variability in saplings of aspen,Populus tremuloides Michx[J].Plant,Cell & Environment,2010,33:1059-1069. [26] Tyree M T,Davis S D,Cochard H.Biophysical perspectives of xylem evolution:is there a trade-off of hydraulic effi-ciency for vulnerabitity to dysfunction?[J].IAWA Journal,1994,15:335-360. [27] Negret B S,Pérez F,Markesteijn L,et al.Diverging drought-tolerance strategies explain tree species distribution along a fog-dependent moist gradient in a temperate rain forest[J].Oecologia,2013,173:625-635. [28] 安峰,张硕新.7种木本植物根和小枝木质部栓塞的脆弱性[J].生态学报,2005,25:1928-1932. [29] 刘存海.黄土丘陵区典型落叶树种的水力学特性研究[D].陕西杨凌:中国科学院教育部水土保持与生态环境研究中心,2014. [30] 王爱英.西双版纳石灰山三种常绿优势树种水力特征的季节变化及其对干旱胁迫的适应机制[D].北京:中国科学院西双版纳热带植物园,2008. [31] 陈伟月.陕北水蚀风蚀交错带沙柳和柠条水力抗旱策略研究[D].陕西杨凌:西北农林科技大学,2015. |