庐山针阔混交林优势种水分利用来源季节变化及对降水的响应

doi:10.13287/j.1001-9332.202404.015

摘要/Abstract

摘要： 阐明亚热带湿润山地林区针阔混交林优势种水分来源的季节规律,解析共生植物水文生态位分配与竞争机制,探究植物水分利用对降水的响应,可为指导植被经营管理提供理论参考。本研究以庐山山区马尾松与栓皮栎混交林为对象,基于氢氧稳定同位素技术,分析降水、马尾松和栓皮栎木质部水及0～100 cm土壤水的δ²H和δ¹⁸O特征,采用MixSIAR模型、Levins指数和PS指数分别计算各水源的相对贡献率、马尾松与栓皮栎的水文生态位宽度和生态位重叠度。结果表明: 丰水期(3—7月)马尾松主要利用0～20和20～40 cm土壤水,栓皮栎主要利用20～40和40～60 cm土壤水,但在枯水期(8—9月)马尾松和栓皮栎分别转而利用40～60和60～80 cm土壤水,根系吸水深度增加。生长季早期(3—4月)和末期(9月)马尾松与栓皮栎水文生态位重叠度高,水分竞争激烈,生长季中期(5—8月)合理分配水源,水文生态位分离以满足高蒸腾需求。栓皮栎在降水事件前主要利用60～80和80～100 cm土壤水,降水后利用0～20和20～40 cm土壤水,但马尾松在降水事件前后均主要利用0～20和20～40 cm土壤水。综上,马尾松与栓皮栎的水分利用来源呈现“雨季浅,旱季深”的季节规律,能在生长旺季合理分配水源,根系吸水积极响应土壤水分动态,对极端降水的适应性强,具有较强的水源涵养能力。

关键词: 水分利用来源, 氢氧稳定同位素, 混交林, 极端降水, 贝叶斯混合模型

Abstract: Elucidating the seasonal patterns of water sources for dominant species in the sub-tropical humid mountainous forest, analyzing the eco-hydrological complementarity and competition mechanisms among coexisting species, investigating the responses of plant water utilization to precipitation, could provide a theoretical basis for vegetation restoration and management. Based on the stable hydrogen and oxygen isotope technique, we analyzed the δ²H and δ¹⁸O characteristics of precipitation, xylem water from Pinus massoniana and Quercus variabilis, and soil water from 0-100 cm depth in Mount Lushan, China. The MixSIAR model, Levins index, and PS index were used to calculate the relative contribution rate of each water source, the hydrological niche breadth, and niche overlap of P. massoniana and Q. variabilis. The results showed that, in the wet season (March to July), P. massoniana primarily utilized soil water from the 0-20 cm and 20-40 cm depths, while Q. variabilis primarily utilized that from the 20-40 cm and 40-60 cm depths. During the dry season (August to September), P. massoniana and Q. variabilis utilized 40-60 cm and 60-80 cm of soil water, respectively, resulting in an increase in the depth of water absorption. In the early growing season (March to April) and the late growing season (September), there was a high hydrological niche overlap between P. massoniana and Q. variabilis, resulting in intensitive water competition. In the middle of the growing season (May to August), the water source was adequately allocated, and the hydrolo-gical niche was segregated to meet the high transpiration demand. Q. variabilis primarily utilized soil water from a depth of 60-80 cm and 60-80 cm before a precipitation event, and from a depth of 0-20 cm and 20-40 cm after the event. In contrast, P. massoniana primarily utilized soil water from a depth of 0-20 cm and 20-40 cm both before and after a precipitation event. In conclusion, water utilization patterns of P. massoniana and Q. variabilis exhibited a seasonal trend, with shallow water uptake during the rainy season and deep water uptake during the dry season. These species are capable of efficiently allocating water resources during the peak growth season, and their root systems actively respond to change in soil moisture level. They have strong adaptability to extreme precipitation events and exhibit remarkable water conservation capabilities.

Key words: water use source, hydrogen and oxygen stable isotope, mixed forest, extreme precipitation, Bayesian mixing model

雷自然, 王欣, 余新晓, 贾国栋. 庐山针阔混交林优势种水分利用来源季节变化及对降水的响应[J]. 应用生态学报, 2024, 35(4): 886-896.

LEI Ziran, WANG Xin, YU Xinxiao, JIA Guodong. Seasonal variation of water utilization sources and responses to precipitation in the dominant species of broad-leaved and needle-leaved mixed forests in Mount Lushan, China[J]. Chinese Journal of Applied Ecology, 2024, 35(4): 886-896.

参考文献

[1] 史军, 崔林丽, 顾宇丹, 等. 气候变化背景下复合极端事件研究进展. 地球科学进展, 2023, 38(8): 771-779
[2] Jasechko S, Sharp ZD, Gibson JJ, et al. Terrestrial water fluxes dominated by transpiration. Nature, 2013, 496: 347-350
[3] Dubbert M, Werner C. Water fluxes mediated by vegetation: Emerging isotopic insights at the soil and atmosphere interfaces. New Phytologist, 2019, 221: 1754-1763
[4] Chen C, Park T, Wang XH, et al. China and India lead in greening of the world through land-use management. Nature Sustainability, 2019, 2: 122-129
[5] Grossiord C, Granier A, Gessler A, et al. The influence of tree species mixture on ecosystem-level carbon accumulation and water use in a mixed boreal plantation. Forest Ecology and Management, 2013, 298: 82-92
[6] Liu CLC, Kuchma O, Krutovsky KV. Mixed-species versus monocultures in plantation forestry: Development, benefits, ecosystem services and perspectives for the future. Global Ecology and Conservation, 2018, 15: e00419
[7] Silvertown J, Araya Y, Gowing D. Hydrological niches in terrestrial plant communities: A review. Journal of Ecology, 2015, 103: 93-108
[8] Wang J, Fu BJ, Wang LX, et al. Water use characteristics of the common tree species in different plantation types in the Loess Plateau of China. Agricultural and Forest Meteorology, 2020, 288-289: 108020
[9] Zhang BB, Xu Q, Gao DQ, et al. Altered water uptake patterns of Populus deltoides in mixed riparian forest stands. Science of the Total Environment, 2020, 706: 135956
[10] Gao XD, Li HC, Zhao XN, et al. Identifying a suitable revegetation technique for soil restoration on water-limi-ted and degraded land: Considering both deep soil moisture deficit and soil organic carbon sequestration. Geoderma, 2018, 319: 61-69
[11] Tiemuerbieke B, Min XJ, Zang YX, et al. Water use patterns of co-occurring C₃ and C₄ shrubs in the Gurbantonggut Desert in northwestern China. Science of the Total Environment, 2018, 634: 341-354
[12] Yang B, Wen XF, Sun XM. Seasonal variations in depth of water uptake for a subtropical coniferous plantation subjected to drought in an East Asian monsoon region. Agricultural and Forest Meteorology, 2015, 201: 218-228
[13] Rothfuss Y, Javaux M. Reviews and syntheses: Isotopic approaches to quantify root water uptake: A review and comparison of methods. Biogeosciences, 2017, 14: 2199-2224
[14] Ellsworth PZ, Williams DG. Hydrogen isotope fractionation during water uptake by woody xerophytes. Plant and Soil, 2007, 291: 93-107
[15] Ehleringer JR, Dawson TE. Water uptake by plants: Perspectives from stable isotope composition. Plant, Cell & Environment, 1992, 15: 1073-1082
[16] Sprenger M, Leistert H, Gimbel K, et al. Illuminating hydrological processes at the soil vegetation-atmosphere interface with water stable isotopes. Reviews of Geophy-sics, 2016, 54: 674-704
[17] Phillips DL, Gregg JW. Source partitioning using stable isotopes: Coping with too many sources. Oecologia, 2003, 136: 261-269
[18] Stock BC, Jackson AL, Ward EJ, et al. Analyzing mixing systems using a new generation of Bayesian tracer mixing models. PeerJ, 2018, 6: e5096
[19] Jia GD, Nehemy MF, Chen LX, et al. Ephemeral connectivity between trees and groundwater in a temperate forest in China. Journal of Hydrology, 2022, 610: 127887
[20] Stock BC, Semmens BX. Unifying error structures in commonly used biotracer mixing models. Ecology, 2016, 97: 2562-2569
[21] Landwehr J, Coplen TB. Line-conditioned excess: A new method for characterizing stable hydrogen and oxygen isotope ratios in hydrologic systems// IAEA, ed. International Conference on Isotopes in Environmental Studies. Vienna: IAEA, 2006: 132-135
[22] Barbeta A, Jones SP, Clavé L, et al. Unexplained hydrogen isotope offsets complicate the identification and quantification of tree water sources in a riparian forest. Hydrology and Earth System Sciences, 2019, 23: 2129-2146
[23] Levins R. Evolution in Changing Environments: Some Theoretical Explorations. Princeton, NJ, USA: Princeton University Press, 1968
[24] Han L, Liu LL, Peng L, et al. Mixing of tree species with the same water use strategy might lead to deep soil water deficit. Forest Ecology and Management, 2023, 534: 120876
[25] Liu ZQ, Yu XX, Jia GD, et al. Contrasting water sources of evergreen and deciduous tree species in rocky mountain area of Beijing, China. Catena, 2017, 150: 108-115
[26] Jia GD, Liu ZQ, Chen LX, et al. Distinguish water utilization strategies of trees growing on earth-rocky mountainous area with transpiration and water isotopes. Ecology and Evolution, 2017, 7: 10640-10651
[27] Wang J, Fu BJ, Lu N, et al. Seasonal variation in water uptake patterns of three plant species based on stable isotopes in the semi-arid Loess Plateau. Science of the Total Environment, 2017, 609: 27-37
[28] Zhou H, Zhao W, Zhang G. Varying water utilization of Haloxylon ammodendron plantations in a desert-oasis ecotone. Hydrological Processes, 2017, 31: 825-835
[29] 张欢, 曹俊, 王化冰, 等. 张北地区退化杨树防护林的水分利用特征. 应用生态学报, 2018, 29(5): 1381-1388
[30] 刘自强, 余新晓, 贾国栋, 等. 北京山区侧柏利用水分来源对降水的响应. 林业科学, 2018, 54(7): 16-23
[31] Wu Z, Behzad HM, He QF, et al. Seasonal transpiration dynamics of evergreen Ligustrum lucidum linked with water source and water-use strategy in a limestone karst area, southwest China. Journal of Hydrology, 2021, 597: 126199
[32] Dai JJ, Zhang XP, Wang L, et al. Water stable isotope characteristics and water use strategies of co-occurring plants in ecological and economic forests in subtropical monsoon regions. Journal of Hydrology, 2023, 621: 129565
[33] Zhu WR, Li WH, Shi PL, et al. Intensified interspeci-fic competition for water after afforestation with Robinia pseudoacacia into a native shrubland in the Taihang Mountains, Northern China. Sustainability, 2021, 13: 807
[34] 杨菲, 林毅雁, 陈立欣, 等. 晋西黄土区油松和刺槐2种人工林内乔灌优势种的土壤水分利用及水分生态位特征. 林业科学, 2022, 58(6): 1-12
[35] Guo JS, Hungate BA, Kolb TE, et al. Water source niche overlap increases with site moisture availability in woody perennials. Plant Ecology, 2018, 219: 719-735
[36] Forrester D. The spatial and temporal dynamics of species interactions in mixed species forests: From pattern to process. Forest Ecology and Management, 2014, 312: 282-292
[37] Wu JE, Zeng HH, Zhao F, et al. Plant hydrological niches become narrow but stable as the complexity of interspecific competition increases. Agricultural and Forest Meteorology, 2022, 320: 108953
[38] Liu ZQ, Jia GD, Yu XX, et al. Water use by broadleaved tree species in response to changes in precipita-tion in a mountainous area of Beijing. Agriculture, Ecosystems and Environment, 2018, 251: 132-140
[39] 赵娜, 孟平, 何雅冰, 等. 北京山区侧柏-荆条系统水分来源对降雨事件的响应. 应用生态学报, 2017, 28(7): 2155-2163
[40] Brum M, Vadeboncoeur MA, Ivanov V, et al. Hydrolo-gical niche segregation defines forest structure and drought tolerance strategies in a seasonal Amazon forest. Journal of Ecology, 2019, 107: 318-333