郭建荣. 2017. 木本植物银腺杨根压及其昼夜周期与影响因素的研究.北京:中国林业科学研究院博士学位论文. (Guo J R. 2017. Researching of root pressure and its diurnal rhythm of 84K pupolar and the influencing factors.Beijing: PhD thesis of Chinese Academy of Forestry.[in Chinese]) 靳 欣, 徐 洁, 白坤栋, 等. 2011. 从水力结构比较3种共存木本植物的抗旱策略. 北京林业大学学报, 33(6): 135-141. (Jin X, Xu J, Bai K D,et al. 2011. Comparison of drought strategies of three co-existing woody plants by their hydraulic structures. Journal of Beijing Forestry University, 33(6): 135-141. [in Chinese]) 万贤崇, 孟 平. 2007. 植物体内水分长距离运输的生理生态学机制. 植物生态学报, 31(5): 804-813. (Wan X C, Meng P. 2007.Physiological and ecological mechanisms of long-distance water transport in plants: a review of recent issues. Chinese Journal of Plant Ecology, 31(5): 804-813. [in Chinese]) 王 林, 冯锦霞, 王双霞, 等. 2013a. 干旱和坡向互作对栓皮栎和侧柏生长的影响. 生态学报, 33(8): 2425-2433. (Wang L, Feng J X, Wang S X,et al. 2013a. The interaction of drought and slope aspect on growth of Quercus variabilis and Platycladus orientalis. Acta Ecologica Sinica, 33(8): 2425-2433. [in Chinese]) 王 林, 冯锦霞, 万贤崇. 2013b. 土层厚度对刺槐旱季水分状况和生长的影响. 植物生态学报, 37(3): 248-255. (Wand L, Feng J X, Wan X C. 2013b. Effects of soil thickness on dry-season water relations and growth in Robinia pseudoacacia. Chinese Journal of Plant Ecology, 37(3): 248-255. [in Chinese]) 王 林, 代永欣, 樊兴路, 等. 2015. 风对黄花蒿水力学性状和生长的影响. 生态学报, 35(13): 4454-4461. (Wang L, Dai Y X, Fan X L,et al. 2015. Effects of wind on hydraulic properties and growth of Artemisia annua Linn. Acta Ecologica Sinica, 35(13): 4454-4461. [in Chinese]) 王 林, 代永欣, 郭晋平, 等. 2016. 刺槐苗木干旱胁迫过程中水力学失败和碳饥饿的交互作用. 林业科学, 52(6): 1-9. (Wang L, Dai Y X, Guo J P,et al. 2016. Interaction of hydraulic failure and carbon starvation on Robinia pseudoacacia seedlings during drought. Scientia Silvae Sinicae, 52(6): 1-9. [in Chinese]) Allen C D, Macalady A K, Chenchouni H, et al. 2010. A global overview of drought and heat-induced tree mortality reveals emerging climate change risks for forests. Forest Ecology and Management, 259(4): 660-684. Anderegg W R, Callaway E S. 2012.Infestation and hydraulic consequences of induced carbon starvation. Plant Physiology, 159(4): 1866-1874. Anderegg W R, Anderegg L D. 2013. Hydraulic and carbohydrate changes in experimental drought-induced mortality of saplings in two conifer species. Tree Physiology, 33(3): 252-260. Araya T, Noguchi K, Terashima I. 2006. Effects of carbohydrate accumulation on photosynthesis differ between sink and source leaves of Phaseolus vulgaris L. Plant and Cell Physiology, 47(5): 644-652. Christman M A, Sperry J S, Smith D D. 2012. Rare pits, large vessels and extreme vulnerability to cavitation in aring-porous tree species. New Phytologist, 193(3): 713-720. Dietze M C, Sala A, Carbone M S,et al. 2014. Nonstructural carbon in woody plants. Annual Review of Plant Biology, 65(1): 667-687. Domec J C, Scholz F G, Meinzer F C,et al. 2006. Diurnal and seasonal variation in root xylem embolism in neotropical savanna woody species: impact on stomatal control of plant water status. Plant Cell and Environment, 29(1): 26-35. Domec J C, Pruyn M L. 2008.Bole girdling affects metabolic properties and root, trunk and branch hydraulics of young ponderosa pine trees. Tree Physiology, 28(10): 1493-1504. Hartmann H. 2011. Will a 385 million year-struggle for light become a struggle for water and for carbon?-How trees may cope with more frequent climate change-type drought events. Global Change Biology, 17(1): 642-655. Hartmann H, Ziegler W, Trumbore S. 2013.Lethal drought leads to reduction in nonstructural carbohydrates in Norway spruce tree roots but not in the canopy. Functional Ecology, 27(2): 413-427. Kosola K R,Dickmann D I, Paul E A, et al. 2001. Repeated insect defoliation effects on growth, nitrogen acquisition, carbohydrates, and root demography of poplars. Oecologia, 129(1): 65-74. Landhäusser S M, Lieffers V J. 2012. Defoliation increases risk of carbon starvation in root systems of mature aspen.Trees, 26(2): 653-661. McDowell N G, Pockman W T, Allen C D,et al. 2008. Mechanisms of plant survival and mortality during drought: Why do some plants survive while others succumb to drought? New Phytologist, 178(4): 719-739. McDowell N G, Sevanto S. 2010. The mechanisms of carbon starvation: How, when, or does it even occur at all? New Phytologist, 186(2): 264-266. McDowell N G. 2011. Mechanisms linking drought, hydraulics, carbon metabolism, and vegetation mortality. Plant Physiology, 155(3): 1051-1059. Menezes-Silva P E, Cavatte P C, Martins S C, et al. 2015. Wood density, but not leaf hydraulic architecture, is associated with drought tolerance in clones of Coffea canephora. Trees, 29(6): 1-11. Mitchell P J, O’Grady A P, Tissue D T,et al. 2013. Drought response strategies define the relative contributions of hydraulic dysfunction and carbohydrate depletion during tree mortality. New Phytologist, 197(3): 862-872. O’Brien M J, Leuzinger S, Philipson C D,et al. 2014. Drought survival of tropical tree seedlings enhanced by non-structural carbohydrate levels. Nature Climate Change, 4(8): 710-714. Palacio S, Hoch G, Sala A,et al. 2014. Does carbon storage limit tree growth? New Phytologist, 201(4): 1096-1100. Pangle R E, Limousin J M, Plaut J A, et al. 2015. Prolonged experimental drought reduces plant hydraulic conductance and transpiration and increases mortality in a piñon-juniper woodland. Ecology and Evolution, 5(8): 1618-1638. Sala A, Woodruff D R, Meizer F C. 2012. Carbon dynamics in trees: feast or famine. Tree Physiology, 32(6): 764-775. Salleo S, Lo Gullo M A, Paoli D D,et al. 1996. Xylem recovery from cavitation-induced embolism in young plants of laurus nobilis: a possible mechanism. New Phytologist, 132(1): 47-56. Salleo S, Lo Gullo M A, Trifilò P,et al. 2004. New evidence for a role of vessel-associated cells and phloem in the rapid xylem refilling of cavitated stems of laurus nobilis L. Plant Cell and Environment, 27(8): 1065-1076. Salmon Y,Torres-Ruiz J M, Poyatos R, et al. 2015. Balancing the risks of hydraulic failure and carbon starvation: a twig scale analysis in declining Scots pine. Plant Cell and Environment, 38(12): 2575-2588. Secchi F, Zwieniecki M. 2011. Sensing embolism in xylem vessels: the role of sucrose as a trigger for refilling. Plant, Cell and Environment, 34(3): 514-524. Sellin A, Niglas A, Õunapuu E. 2013. Impact of phloem girdling on leaf gas exchange and hydraulic conductance in hybrid aspen. Biologia Plantarum, 57(3): 531-539. Sevanto S, McDowell N G, Dickman L T,et al. 2014. How do trees die? A test of the hydraulic failure and carbon starvation hypotheses. Plant, Cell and Environment, 37(1): 153-161. Sigurdsson B D, Medhurst J L, Wallin G, et al. 2013. Growth of mature boreal Norway spruce was not affected by elevated [CO2] and/or air temperature unless nutrient availability was improved. Tree Physiology, 33(11): 1192-1205. Tyree M T, Cochard H, Cruiziat P,et al. 1993. Drought-induced leaf shedding in walnut: evidence for vulnerability segmentation. Plant, Cell and Environment, 16(7): 879-882. Tyree M T. 2003. Plant hydraulics: the ascent of water. Nature, 423(6943): 923. Wiley E, Helliker B. 2012. Are-evaluation of carbon storage in trees lends greater support for carbon limitation to growth. New Phytologist, 195(2): 285-289. Wiley E, Huepenbecker S, Casper B B,et al. 2013. The effects of defoliation on carbon allocation: can carbon limitation reduce growth in favour of storage? Tree Physiology, 33(11): 1216-1228. Woodruff D R. 2014. The impacts of water stress on phloem transport inDouglas-fir trees. Tree Physiology, 34(1): 5-14. Zhang T, Cao Y, Chen Y,et al. 2015. Non-structural carbohydrate dynamics in Robinia pseudoacacia saplings under three levels of continuous drought stress. Trees, 29(6): 1837-1849. |