Water use strategy of Eucalyptus urophylla ×E. grandis on karst hillslope based on isotope analysis.

doi:10.13287/j.1001-9332.201609.029

Abstract

Abstract: Using stable isotope techniques, water sources and water use efficiencies of Eucalyptus urophylla ×E. grandis (exotic tree species) and Liquidambar formosana (native tree species, as a reference) were studied in a typical karst artificial forest, and the risk of drought stress of the plantation was discussed. The results showed that the isotope value of shallow soil water (0-50 cm) had obvious gradient features and was similar to the recent rain, while that of deep water was more stable and different from the shallow soil water. The soil water content in wet season (May and September) was higher than in dry season (October), and was higher in upslope than in downslope segment. The main water source of L. formosana was shallow soil water, which corresponded to high water use efficiency in different seasons. The main water sources for E. urophylla ×E. grandis on the upper slope and downslope segments were both shallow soil water in wet season, however, the sum of average water using the proportion of deep soil water increased for the downslope segment in the end of wet season. In dry season, E. urophylla ×E. grandis on the downslope segment mainly used shallow soil water, while it used deeper soil water on the upslope segment when soil water was relatively low. Meanwhile, the water use efficiency of E. urophylla ×E. grandis was lower compared with L. formosana, which revealed E. urophylla ×E. grandis did not get enough water supply under drought stress. The above results indicated that E. urophylla ×E. grandis would encounter high risk of water stress if extreme drought events happened in karst regions in the coming future.

DING Ya-li, CHEN Hong-song, NIE Yun-peng, WANG Sheng, ZHANG Hui-ling, WANG Ke-lin. Water use strategy of Eucalyptus urophylla ×E. grandis on karst hillslope based on isotope analysis.[J]. Chinese Journal of Applied Ecology, 2016, 27(9): 2729-2736.

References

[1] Yuan D-X (袁道先). On the environmental and geolo-gic problems of Karst mountains and rocks in Southwest China. World Science-Technology Research & Development (世界科技研究与发展), 1997, 19(5): 41-43 (in Chinese)
[2] Jiang ZC, Lian YQ, Qin XQ. Rocky desertification in Southwest China: Impacts, causes, and restoration. Earth-Science Reviews, 2014, 132: 1-12
[3] Chinese Academy of Sciences (中国科学院). Some suggestions of carrying forward the comprehensive harnessing desertification in southwest Karst region. Advance in Earth Sciences (地球科学进展), 2003, 18(4): 489-492 (in Chinese)
[4] Bai J-Y (白嘉雨), Gan S-M (甘四明). Social, economical and ecological significance of Eucalyptus planation. World Forest Research (世界林业研究), 1996, 9(2): 63-68 (in Chinese)
[5] Qi S-X (祁述雄). Eucalyptus in China. 2nd Ed. Beijing: China Forestry Press, 2002: 22 (in Chinese)
[6] Huang G-Q (黄国勤), Zhao Q-G (赵其国). The history, status quo, ecological problems and countermea-sures of Eucalyptus plantations in Guangxi. Acta Ecologica Sinica (生态学报), 2014, 34(18): 5142-5152 (in Chinese)
[7] Mensforth LJ, Thorburn PJ, Tyerman SD, et al. Sources of water used by riparian Eucalyptus camaldulensis overlying highly saline groundwater. Oecologia, 1994, 100: 21-28
[8] Knight JH. Root distributions and water uptake patterns in Eucalypts and other species// Landsberg J, ed. The Ways Trees Use Water. Water and Salinity Issues in Agroforestry. Canberra: Rural Industries Research and Development Corporation, 1999: 55-78
[9] Dye PJ. Response of Eucalyptus grandis trees to soil water deficits. Tree Physiology, 1996, 16: 233-238
[10] White DA, Dunin FX, Turner NC, et al. Water use by contour-planted belts of trees comprised of four Eucalyptus species. Agricultural Water Management, 2002, 53: 133-152
[11] Ping L (平亮), Xie Z-Q (谢宗强). Effects of introducing Eucalyptus on indigenous biodiversity. Chinese Journal of Applied Ecology (应用生态学报), 2009, 20(7): 1765-1774 (in Chinese)
[12] Ehleringer JR, Cooper TA. Correlations between carbon isotope ratio and microhabitat in desert plants. Oecologia, 1988, 76: 562-566
[13] Ehleringer JR, Roden J, Dawson TE. Assessing ecosystem-level water relations through stable isotope ratio analyses// Sala OE, Jackson RB, Mooney HA, eds. Me-thods in Ecosystem Science. New York: Springer, 2000: 181-214
[14] Turner NC, Schulze ED, Nicolle D, et al. Growth in two common gardens reveals species by environment interaction in carbon isotope discrimination of Eucalyptus. Tree Physiology, 2010, 30: 741-747
[15] Zahid FR, Shah FUR, Majeed A. Planting Eucalyptus camaldulensis in arid environment: Is it useful species under water deficit system. Pakistan Journal of Botany, 2010, 42: 1733-1744
[16] Yuan Y-H (袁颖红), Fan H-B (樊后保), Wu J-P (吴建平), et al. The photosynthesis characteristics and water use efficiency of Eucalyptus urophylla ×E. grandis plantations of different ages. Chinese Journal of Applied and Environmental Biology (应用与环境生物学报), 2016, 22(1): 58-63 (in Chinese)
[17] Qiu Q (邱权), Pan X (潘昕), Li J-Y (李吉跃), et al. Water consumption characteristics and water use efficiency of Eucalyptus urophylla ×Eucalyptus grandis and bamboo-willow seedlings. Acta Ecologica Sinica (生态学报), 2014, 34(6): 1401-1410 (in Chinese)
[18] Swaffer BA, Holland KL, Doody TM, et al. Water use strategies of two co-occurring tree species in a semi-arid karst environment. Hydrological Processes, 2014, 28: 2003-2017
[19] Chen T (陈婷), Ma J-M (马姜明), Liang S-C (梁士楚). Study on the adaptability of Eucalyptus grandis ×E. urophylla in karst hills.Ⅰ. Photosynthetic physiological ecology characteristics in spring. Guihaia (广西植物), 2012, 32(2): 185-191 (in Chinese)
[20] Liu MX, Xu XL, Sun AY. Decreasing spatial variability in precipitation extremes in southwestern China and the local/large-scale influencing factors. Journal of Geophy-sical Research: Atmospheres, 2015, 120: 6480-6488
[21] China Forest Compiler Committee (中国森林编辑委员会). China Forest Ⅲ. Beijing: China Forestry Press, 1999: 1431-1434 (in Chinese)
[22] Yang M-S (杨民胜), Wu Z-H (吴志华), Chen S-X (陈少雄). Progress in the research of Eucalyptus in China and its scientific management. Eucalypt Science & Technology (桉树科技), 2006, 23(1): 32-39 (in Chinese)
[23] Song T-Q (宋同清), Peng W-X (彭晚霞), Zeng F-P (曾馥平), et al. Spatial pattern of forest communities and environmental interpretation in Mulun National Nature Reserve, karst cluster-peak depression region. Chinese Journal of Plant Ecology (植物生态学报), 2010, 34(3): 298-308 (in Chinese)
[24] Zhang J-G (张继光), Chen H-S (陈洪松), Su Y-R (苏以荣), et al. Variability of soil moisture and its relationship with environmental factors on Karst hillslope. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2010, 26(9): 87-93 (in Chinese)
[25] Wu M (吴敏), Liu S-J (刘淑娟), Ye Y-Y (叶莹莹), et al. Spatial variation of surface soil organic carbon and its influencing factor in cultivated slopes and abandoned lands in a Karst peak-cluster depression area. Acta Ecologica Sinica (生态学报), 2016, 36(6): 1619-1627 (in Chinese)
[26] Hu K (胡可), Chen H-S (陈洪松), Nie Y-P (聂云鹏), et al. Characteristics of seasonal variation of deuterium and oxygen-18 isotope composition of precipitation in karst peak-cluster depression area, northwest Guangxi of China. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2013, 29(5): 53-62 (in Chinese)
[27] Phillips DL, Gregg JW. Source partitioning using stable isotopes: Coping with too many sources. Oecologia, 2003, 136: 261-269
[28] Nie YP, Chen HS, Wang KL, et al. Rooting characte-ristics of two widely distributed woody plant species growing in different karst habitats of southwest China. Plant Ecology, 2014, 215: 1099-1109
[29] Zohar Y. Root distribution of a eucalypt shelterbelt. Fo-rest Ecology and Management, 1985, 12: 305-307
[30] Wang E-Q (王恩群), Yu X-B (余雪标), Lin P-Q (林培群), et al. Research on root system of Eucalyptus-crops interplanting with extra-big row. Guangdong Agricultural Sciences (广东农业科学), 2010, 37(3): 72-75 (in Chinese)
[31] Schenk HJ, Jackson RB. The global biogeography of roots. Ecological Monographs, 2002, 72: 311-328
[32] Chen H-S (陈洪松), Nie Y-P (聂云鹏), Wang K-L (王克林). Spatio-temporal heterogeneity of water and plant adaptation mechanisms in karst regions: A review. Acta Ecologica Sinica (生态学报), 2013, 33(2): 317-326 (in Chinese)
[33] Liu S-J (刘淑娟), Zhang W (张伟), Wang K-L (王克林), et al. Spatiotemporal heterogeneity and its formation causes of soil physical properties in karst peak-cluster depression area of northwest Guangxi, China. Chinese Journal of Applied Ecology (应用生态学报), 2010, 21(9): 2249-2256 (in Chinese)
[34] Fu TG, Chen HS, Zhang W, et al. Spatial variability of surface soil saturated hydraulic conductivity in a small karst catchment of southwest China. Environmental Earth Sciences, 2015, 74: 2381-2391
[35] Nie YP, Chen HS, Wang KL, et al. Seasonal water use patterns of woody species growing on the continuous dolostone outcrops and nearby thin soils in subtropical China. Plant and Soil, 2011, 341: 399-412
[36] Hasselquist NJ, Allen MF, Santiago LS. Water relations of evergreen and drought-deciduous trees along a seaso-nally dry tropical forest chronosequence. Oecologia, 2010, 164: 881-890