Hydrological effects of litters and soil of seven Magnoliaceae ornamental plants
ZHOU Lingfeng1,2, CHEN Suyi1, DAI Jinjun3, LIU Jundong1, XU Lizhen1, TIAN Zhujun1, ZHAN Zhaohui1, ZHAO Wendi1, CHEN Jinhui1,2, TU Zhihua1,2
1. Key Laboratory of Genetics and Germplasm Innovation of Tropical Special Forest Trees and Ornamental Plants, Ministry of Education, College of Forestry, Hainan University, 570228 Haikou, China; 2. Engineering Research Center of Rare and Precious Tree Species in Hainan Province, 570228 Haikou, China; 3. Hainan Hydrology and Water Resources Survey Bureau, 570203 Haikou, China
Abstract:[Background] Magnoliaceae plants resources is rich in China, which have widely been used in making landscape to demonstrate gardens and cultural connotation by making full use of its aesthetic functions such as posture, culture and good views, and which was introduced in Hainan Tianxiang Magnolia Plant Conservation Research Center in Danzhou county of Hainan province, but lack of understanding the ecological service functions such as soil and water conservation of Magnoliaceae plants in this region. It is of great significance for rational introduction based on the water-holding capacity of each Magnoliaceae plants to render the Magnoliaceae plants configuration more reasonable in garden application. [Methods] Seven common Magnoliaceae plants (Michelia shiluensis, Michelia crassipes, Michelia foveolata, Michelia maudiae, Michelia odora, Manglietiastrum sinicum, Manglietia lucida) in Hainan were selected as the research objects, and the water-holding function of litter layer and soil layer of different Magnoliaceae plants were determined by quantitatively research with immersion method and cutting-ring method. [Results] 1) The litter volume of the seven plants was about 5.24-25.11t/hm2, which followed the order of M.shiluensis>M.crassipes>M.foveolata>M.sinicum>M.maudiae>M.odora>M.lucida. The decomposition degree of dead branches and leaves of Manglietia lucida was high. 2) The maximum water-holding capacity of litter layer varied from 14.32 to 25.45t/hm2. The modified interception amount was 15.88-53.85t/hm2, which followed the order of M.shiluensis>M.crassipes>M.foveolata>M.sinicum>M.odora>M.lucida>M.maudiae. The water-holding function of M.shiluensis and M.crassipes litter layer was good. 3) Semi-decomposed litter could be saturated in 8 h and undecomposed litter reached saturation in 10h, the water-holding capacity had logarithmic relationship with soaking time (R2>0.92); the absorption rate changed the most within the first 2h of soaking and there was a power function relationship between water absorption rate and soaking time (R2>0.94). 4) The mean soil bulk density of different plants varied from 1.22g/cm3 to 1.55g/cm3, and the total porosity varied from 40.03% to 49.89%. The saturate soil water holding capacity was about 400.34-498.95t/hm2, and the effective soil water-holding capacity was about 26.23-70.33t/hm2. The water-holding capacity of the soil layer was in the order of M.foveolata>M.crassipes>M.lucida>M.shiluensis>M.odora>M.sinicum>M.maudiae. A significant power function relation between infiltration rate and infiltration fitting time was found (R2>0.90). [Conclusions] The water conservation capacity of soil layer is higher than that of litter layer, which is the main part for hydrological effect of forest land. The water conservation capacity of M.shiluensis, M.crassipes and M.foveolata is better than those of other Magnoliaceae plants, which suggested to give priority to the mixed planting of M.shiluensis, M.crassipes and M.foveolata in the application of landscape.
杜金鸿, 刘方正, 周越, 等. 自然保护地生态系统服务价值评估研究进展[J]. 环境科学研究, 2019, 32(9): 1475. DU Jinhong, LIU Fangzheng, ZHOU Yue, et al. A review of ecosystem services assessment and valuation of protected areas[J]. Research of Environmental Sciences, 2019, 32(9): 1475.
[2]
贾剑波, 刘文娜, 余新晓, 等. 半城子流域3种林地枯落物的持水能力[J]. 中国水土保持科学, 2015, 13(6): 26. JIA Jianbo, LIU Wenna, YU Xinxiao, et al. Water-holding characteristics of litters in three types of forest in the upper reaches of Banchengzi Basin[J]. Science of Soil and Water Conservation, 2015, 13(6): 26.
[3]
PARK A, FRIESEN P, SERRUD A A S. Comparative water fluxes through leaf litter of tropical plantation trees and the invasive grass Saccharum spontaneum in the Republic of Panama[J]. Journal of Hydrology, 2010, 383(3): 167.
[4]
MORI A S, LERTZMAN K P, GUSTAFASSON L. Biodiversity and ecosystem services in forest ecosystems: A research agenda for applied forest ecology[J]. Journal of Applied Ecology, 2017, 54(1): 12.
[5]
涂志华, 范志平, 孙学凯, 等. 大伙房水库流域不同植被类型枯落物层和土壤层水文效应[J]. 水土保持学报, 2019, 33(1): 127. TU Zhihua, FAN Zhiping, SUN Xuekai, et al. Hydrological effects of litters layer and soil layer in different vegetation types in Dahuofang Watershed[J]. Journal of Soil and Water Conservation, 2019, 33(1): 127.
[6]
FERRAZ S F B, LIMA W D P, RODRIGUES C B. Managing forest plantation landscapes for water conservation[J]. Forest Ecology and Management, 2013(301): 58.
[7]
ZHANG M F, LIU N, HARPER R, et al. A global review on hydrological responses to forest change across multiple spatial scales: Importance of scale, climate, forest type and hydrological regime[J]. Journal of Hydrology, 2017(546): 44.
[8]
周凌峰, 戴矜君, 黄艳萍, 等. 9种景观植物枯落物层及其土壤层水文效应[J]. 生态科学, 2022, 41(3): 90. ZHOU Lingfeng, DAI Jinjun, HUANG Yanping, et al. Hydrological effects of litters and soil of nine landscape plants[J]. Ecological Science, 2022, 41(3): 90.
[9]
BURROWS C R, APPOLD M S. Hydrology of the forest city basin, Mid-Continent, USA: Implications for CO2 sequestration in the St. Peter Sandstone[J]. Environmental Earth Sciences, 2015, 73(4): 1409.
[10]
郭建军, 王佳欢, 胡静霞, 等. 2022年冬奥会崇礼赛区针叶林枯落物及土壤水文效应[J]. 中国水土保持科学, 2021, 19(4): 44. GUO Jianjun, WANG Jiahuan, HU Jingxia, et al. Hydrological effects of litter and soil for the coniferous forest in the Chongli district for 2022 Olympic Winter Games, Hebei province[J]. Science of Soil and Water Conservation, 2021, 19(4): 44.
[11]
梁桂友, 温放, 韦毅刚. 广西野生木兰科植物种质资源及其园林应用[J]. 北方园艺, 2012, 36(10): 117. LIANG Guiyou, WEN Fang, WEI Yigang. Study on the germplasm resources of wild Magnolia and their landscape application in Guangxi[J]. Northern Horticulture, 2012, 36(10): 117.
[12]
田凡, 陈志萍, 李鹤, 等. 贵州乡土木兰科植物园林观赏研究[J]. 北方园艺, 2016, 40(4): 83. TIAN Fan, CHEN Zhiping, LI He, et al. Study on the ornamental of native Magnoliaceae and their landscape in Guizhou province[J]. Northern Horticulture, 2016,40(4): 83.
[13]
陈洁, 宁阳, 金晓玲, 等. 六种木兰科植物种子播种育苗试验[J]. 北方园艺, 2015, 39(9): 53. CHEN Jie, NING Yang, JIN Xiaoling, et al. An experimental on seed collection and planting seedling of six species of Magnoliaceae[J]. Northern Horticulture, 2015, 39(9): 53.
[14]
李江伟, 刘雪英, 肖志飚, 等. 木兰科植物引种适应研究及其园林景观评价[J]. 林业资源管理, 2020(4): 161. LI Jiangwei, LIU Xueying, XIAO Zhibiao, et al. A study on introduction and adaptation of Magnoliaceae plants and its landscape evaluation[J]. Forest Resources Management, 2020(4): 161.
[15]
杨皖乔, 王妙青, 林海龙, 等. 7种木兰科树种物候学特征与新叶生长规律[J]. 福建林业科技, 2018, 45(2): 13. YANG Wanqiao, WANG Miaoqing, LIN Hailong, et al. Phenology of the several species and new leaf growth law of several species of Magnoliaceae[J]. Journal of Fujian Forestry Science and Technology, 2018, 45(2): 13.
[16]
雷翻宇, 黄辉东. 木兰科植物在广西药用植物园园林绿化中的应用现状分析[J]. 现代园艺, 2017(8): 136. LEI Fanyu, HUANG Huidong. Analysis on the application of Magnoliaceae plants in the landscaping of Guangxi Medicinal Botanical Garden[J]. Contemporary Horticulture, 2017(8): 136.
[17]
方晓晨, 王盼, 张雪莹, 等. 浙江木兰科野生观赏植物资源及评价[J]. 热带作物学报, 2018, 39(8): 1513. FANG Xiaochen, WANG Pan, ZHANG Xueying, et al. Resources and evaluation of wild ornamental plants of Magnoliaceae in Zhejiang province[J]. Chinese Journal of Tropical Crops, 2018, 39(8): 1513.
[18]
杨寒月, 张光辉, 张宝军. 黄土丘陵区沟坡典型植物群落枯落物蓄积量及其持水性能[J]. 中国水土保持科学, 2019, 17(3): 83. YANG Hanyue, ZHANG Guanghui, ZHANG Baojun. Litter and its water-holding properties of typical plant communities distributed on gully steep slopes in the loess hilly-gully region[J]. Science of Soil and Water Conservation, 2019, 17(3): 83.
[19]
赵芳, 李雪云, 赖国桢, 等. 飞播马尾松林不同林下植被类型枯落物及土壤水文效应[J]. 中国水土保持科学, 2016, 14(4): 26. ZHAO Fang, LI Xueyun, LAI Guozhen, et al. Hydrological effects of forest litters and soil in different types of understory vegetation in aerially-seeded Pinus massoniana plantation[J]. Science of Soil and Water Conservation, 2016, 14(4): 26.
[20]
胡顺军, 田长彦, 宋郁东, 等. 土壤渗透系数测定与计算方法的探讨[J]. 农业工程学报, 2011, 27(5): 68. HU Shunjun, TIAN Changyan, SONG Yudong, et al. Determination and calculation of soil permeability coefficient [J]. Transactions of the CSAE, 2011, 27(5): 68.
[21]
郑淼. 华北土石山区不同林分类型枯落物及土壤水文生态效应[J]. 中国水土保持科学, 2020, 18(2): 84. ZHENG Miao. Litter and soil hydro-ecological effects of different stand types in the rocky mountain area of North China[J]. Science of Soil and Water Conservation, 2020, 18(2): 84.
[22]
吴迪, 辛学兵, 裴顺祥, 等. 北京九龙山8种林分的枯落物及土壤水源涵养功能[J]. 中国水土保持科学, 2014, 12(3): 78. WU Di, XIN Xuebing, PEI Shunxiang, et al. Water conservation function of litters and soil of eight kinds of forest stands in Jiulong Mountain in Beijing city[J]. Science of Soil and Water Conservation, 2014, 12(3): 78.
[23]
侯贵荣, 毕华兴, 魏曦, 等. 黄土残塬沟壑区3种林地枯落物和土壤水源涵养功能[J]. 水土保持学报, 2018, 32(2): 357. HOU Guirong, BI Huaxing, WEI Xi, et al. Water conservation function of litters and soil in three kinds of woodlands in gully region of Loess Plateau[J]. Journal of Soil and Water Conservation, 2018, 32(2): 357.
2022, Vol. 20 
