紫色土区香根草不同径级的根系特征与培肥效应

doi:10.11686/cyxb2015189

摘要/Abstract

摘要： 为探讨水土保持先锋物种香根草的培肥效应及其与各径级根系指标间的关系,以裸地为对照,定期分010 cm,1020 cm,2030 cm土层采集土壤和根系样品,常规方法测定土壤有机质、氮、磷、钾的全量和速效养分,WinRHIZO(Pro.2004c)根系分析系统分10个径级测定根系参数(根长、根表面积和根体积)。结果表明:香根草的培肥效应主要体现在有机质上,且此效应随香根草定植时间的延长而增强,其次是全氮,而有效磷和速效钾则出现亏损;香根草小区土壤有机质、有效磷、全钾、速效钾均表现出明显的土壤养分表聚现象,在010 cm土层的含量显著大于其他土层的(P<0.05);0.00 mm<d≤2.00 mm(d为根系直径)是影响土壤有机质含量的主要根径范围,该范围内所有径级的根长密度/根表面积密度/根体积密度均与土壤有机质含量极显著正相关(P<0.01),尤其是径级0.00 mm<d≤0.50 mm,其次是径级1.50 mm<d≤2.00 mm;d=2.00 mm和d=4.50 mm是重要分界线,当0.00 mm<d≤2.00 mm时,香根草各径级的所有根系指标在土层间均表现出显著性差异且与土层深度极显著负相关,其中0.50 mm<d≤1.00 mm径级的相关系数值最大,当2.00 mm<d≤4.50 mm时土壤养分与所有径级的根系指标均无显著性相关;根重密度/根长密度/根表面积密度/根体积密度的最大值均出现在010 cm土层,且根长密度在年际间、土层间均表现出显著性差异。

Abstract: The aim of this study was to determine the effects of Vetiveria zizanioides plants and their roots on soil properties, and define the role of different root diameter classes. The research was conducted in the Purple Soil Area of China. The experiment compared bare control plots with plots planted in V. zizanioides. Soil and root samples were collected regularly from 0-10 cm, 10-20 cm, 20-30 cm soil layers. Contents of soil organic matter, total and available nitrogen, phosphorus, and potassium were measured by conventional methods. Roots were divided into 10 diameter classes measured by a Root Analysis System (WinRHIZO, Pro. 2004c). It was found that: 1) V. zizanioides substantially enhanced the accumulation of soil organic matter, the longer the planted time the greater the effect. V. zizanioides also promoted the accumulation of soil total nitrogen, but the effect was weak compared with organic matter. Both available phosphorus and potassium were depleted in all V. zizanioides plots. 2) The levels of organic matter, available phosphorus, total potassium and available potassium showed topsoil accumulation in all V. zizanioides plots; i.e. over time their levels in the 0-10 cm soil layer increased significantly more than in the 10-20 cm and 20-30 cm soil layers (P<0.05). 3) The root diameter range (d) 0.00 mm<d≤2.00 mm was dominant in affecting soil organic matter. root length density (RLD), Root surface area density (RSAD), and root volume density (RVD) of all diameter classes in this range were significantly and positively correlated with soil organic matter content (P<0.01), with the highest correlation being the 0.00 mm<d≤0.50 mm diameter range and the next highest being the 1.50 mm<d≤2.00 mm range. 4) Root diameters of d=2.00 mm and d=4.50 mm were important classification divisions. When 0.00 mm<d≤2.00 mm, RLD, RSAD, and RVD of all diameter classes showed significant differences between all soil layers and were significantly and negatively correlated with soil layer depth. The maximum correlation coefficient occurred in roots of the 0.50 mm<d≤1.00 mm diameter range. When 2.00 mm<d≤4.50 mm, all root parameters of all diameter classes were uncorrelated with any measured soil parameter. 5) The maximum RLD, RSAD, and RVD occurred in the 0-10 cm soil layer, and RLD differed significantly among all soil layers in the same year or between 2011 and 2013 in the same soil layer.

谌芸, 何丙辉, 练彩霞, 刘志鹏. 紫色土区香根草不同径级的根系特征与培肥效应[J]. 草业学报, 2016, 25(2): 187-197.

CHEN Yun, HE Bing-Hui, LIAN Cai-Xia, LIU Zhi-Peng. Effects of Vetiveria zizanioides roots on soil properties in the Purple Soil Area of China and the role of different root diameter classes[J]. Acta Prataculturae Sinica, 2016, 25(2): 187-197.

参考文献

[1] Mao P, Yang H, Ma X R. Progress in research and utilization of Vetiveria zizanioides . Journal of Agricultural Science and Technology, 2011, 13(1): 88-93.
[2] Xia H P, Ao H X, Liu S Z. The vetiver eco-engineering a biological technique for realizing sustainable development. Chinese Journal of Ecology, 1998, 17(6): 44-50.
[3] Xia H P, Ao H X, Liu S Z, et al . Vitiver grass-an ideal plant for soil and water conservation. Ecologic Science, 1997, 16(1): 75-82.
[4] Dalton P A, Smith R J, Truong P. Vetiver grass hedges for erosion control on a cropped flood plain: hedge hydraulics. Agricultural Water Management, 1996, 31(1): 91-104.
[5] Li J X, He B H, Chen Y, et al . Root distribution features of typical herb plants for slope protection and their effects on soil shear strength. Transactions of the Chinese Society of Agricultural Engineering, 2013, 29(10): 144-152.
[6] Liu W G, Li L X, Xie H R, et al . Effect of soil bulk density on root morphology and biomass of vetiver grass seeding. Acta Prataculturae Sinica, 2015, 24(4): 214-220.
[7] Li J X. Effect of Herb Plants Roots on Slope Reinforcement and Soil Erosion Resistance in the Three Gorges Reservoir Region[D]. Chongqing: Southwest University, 2013.
[8] Pu Y L, Xie D T, Ni J P, et al . Effects of hedgerow patterns on soil shear strength and anti-scouribility on slope farmland in purple soil area. Scientia Agricultura Sinica, 2014, 47(5): 934-945.
[9] Lin C W, Tu S H, Huang J J, et al . The effects of plant hedgerows o soil erosion and soil fertility on sloping farmland in the purple soil area. Acta Ecologica Sinica, 2007, 27(6): 2191-2198.
[10] Chen Y. Effects of Hedgerow on Purple Soil Water Properties and Its Mechanisms[D]. Chongqing: Southwest University, 2012.
[11] Pu Y L. Effects of Hedgerow-crop Patterns on Controlling Nitrogen and Phosphorus Runoff and Evaluation of Comprehensive Ecological Benefits in Slope Farmland[D]. Chongqing: Southwest University, 2013.
[12] Tao J. Time-scale Effect of Different Herb Plant Roots Distribution on Soil Physical and Chemical Properties in the Three Gorges Reservoir Area[D]. Chongqing: Southwest University, 2013.
[13] Liu D H, Li Y. Mechanism of plant roots improving resistance of soil to concentrated flow erosion. Journal of Soil and Water Conservation, 2003, 17(3): 34-37.
[14] Qin C, He B H, Liu Y X, et al . Effects of Hemerocallis root system distribution characteristic on soil nutrients in terrace banks planted for hillslope protection. Acta Prataculturae Sinica, 2013, 22(5): 256-264.
[15] Cheng W J, Cui J Y, Min F H, et al . Root distribution characteristics of three turfgrasses and their impact on soil nutrient content. Acta Prataculturae Sinica, 2009, 18(1): 179-183.
[16] Liu G S. Soil Physical and Chemical Analysis and Profile Description[M]. Beijing: China Standards Press, 1996.
[17] Zhang Q F, Song Y C, You W H. Relationship between plant community secondary succession and soil fertility in Tiantong, Zhejiang Province. Acta Ecologica Sinica, 1999, 19(2): 174-178.
[18] Pu C F, Cai Q G, Yan Z J. Erosion and nutrient cycling in the Vetiveria zizanioides hedgerow intercropping system with fertilization or mulching measures in humid slopeland. Transactions of the Chinese Society of Agricultural Engineering, 2006, 22(5): 55-60.
[19] Nie J, Liao Y L, Xie J, et al . Impacts of biological hedgerow of vetiver on surface runoff and nitrogen loss in vegetable field under natural rainfall. Journal of Soil and Water Conservation, 2009, 23(1): 12-16.
[20] Xia H P, Ao H X, He D Q, et al . A study on vetiver grass in soil amelioration, and soil and moisture conservation. Tropical Geography, 1996, 16(3): 265-270.
[21] Du F, Liang Z S, Xu X X, et al . The community biomass of abandoned farmland and its effects on soil nutrition in the Loess Hilly Region of Northern Shaanxi, China. Acta Ecologica Sinica, 2007, 27(5): 1673-1683.
[22] Han F P, Zheng J Y, Zhang X C. Plant root system distribution and its effect on soil nutrient on slope land converted from farmland in the Loess Plateau. Transactions of the Chinese Society of Agricultural Engineering, 2009, 25(2): 50-55.
[23] Wu Y, Liu S Q, Fu X Q, et al . Study on improving soil’s waterstable aggregates amounts by botanic root. Journal of Soil Erosion and Soil and Water Conservation, 1997, 3(1): 45-49.
[24] Chen S Y, Huang Y Q. Study on the effect of soil’s antierosion capacity by Pinus elliottii Engelm root systems. Journal of Southwest Agricultural University, 2000, 22(5): 468-471.
[1] 毛萍, 杨宏, 马欣荣. 香根草的研究及利用进展. 中国农业科技导报, 2011, 13(1): 88-93.
[2] 夏汉平, 敖惠修, 刘世忠. 香根草生态工程——实现可持续发展的生物技术. 生态学杂志, 1998, 17(6): 44-50.
[3] 夏汉平, 敖惠修, 刘世忠, 等. 香根草——优良的水土保持植物. 生态科学, 1997, 16(1): 75-82.
[5] 李建兴, 何丙辉, 谌芸, 等. 不同护坡草本植物的根系分布特征及其对土壤抗剪强度的影响. 农业工程学报, 2013, 29(10): 144-152.
[6] 刘晚苟, 李良贤, 谢海容, 等. 土壤容重对野生香根草幼苗根系形态及其生物量的影响. 草业学报, 2015, 24(4): 214-220.
[7] 李建兴. 三峡库区不同护坡草本植物根系的固土抗蚀效应研究[D]. 重庆: 西南大学, 2013.
[8] 蒲玉琳, 谢德体, 倪九派, 等. 紫色土区植物篱模式对坡耕地土壤抗剪强度与抗冲性的影响. 中国农业科学, 2014, 47(5): 934-945.
[9] 林超文, 涂仕华, 黄晶晶, 等. 植物篱对紫色土区坡耕地水土流失及土壤肥力的影响. 生态学报, 2007, 27(6): 2191-2198.
[10] 谌芸. 植物篱对紫色土水土特性的效应及作用机理[D]. 重庆: 西南大学, 2012.
[11] 蒲玉琳. 植物篱-农作模式控制坡耕地氮磷流失效应及综合生态效益评价[D]. 重庆: 西南大学, 2013.
[12] 陶俊. 三峡库区不同护坡草本根系分布对土壤理化性质的时间尺度效应[D]. 重庆: 西南大学, 2013.
[13] 刘定辉, 李勇. 植物根系提高土壤抗侵蚀性机理研究. 水土保持学报, 2003, 17(3): 34-37.
[14] 秦川, 何丙辉, 刘永鑫, 等. 生物埂护坡上黄花根系分布特征及其对土壤养分的影响. 草业学报, 2013, 22(5): 256-264.
[15] 成文竞, 崔建宇, 闵凡华, 等. 三种草坪草的根系分布特征及其对土壤养分的影响. 草业学报, 2009, 18(1): 179-183.
[16] 刘光崧. 土壤理化分析与剖面描述[M]. 北京: 中国标准出版社, 1996.
[17] 张庆费, 宋永昌, 由文辉. 浙江天童植物群落次生演替与土壤肥力的关系. 生态学报, 1999, 19(2): 174-178.
[18] 卜崇峰, 蔡强国, 袁再健. 湿润区坡地香根草植物篱农作措施对土壤侵蚀和养分的影响. 农业工程学报, 2006, 22(5): 55-60.
[19] 聂军, 廖育林, 谢坚, 等. 自然降雨条件下香根草生物篱对菜地土壤地表径流和氮流失的影响. 水土保持学报, 2009, 23(1): 12-16.
[20] 夏汉平, 敖惠修, 何道泉, 等. 香根草在土壤改良和水土保持中的作用. 热带地理, 1996, 16(3): 265-270.
[21] 杜峰, 梁宗锁, 徐学选, 等. 陕北黄土丘陵区撂荒草地群落生物量及植被土壤养分效应. 生态学报, 2007, 27(5): 1673-1683.
[22] 韩凤朋, 郑纪勇, 张兴昌. 黄土退耕坡地植物根系分布特征及其对土壤养分的影响. 农业工程学报, 2009, 25(2): 50-55.
[23] 吴彦, 刘世全, 付秀琴, 等. 植物根系提高土壤水稳性团粒含量的研究. 土壤侵蚀与水土保持学报, 1997, 3(1): 45-49.
[24] 陈士银, 黄月琼. 湿地松林根系对土壤抗侵蚀能力影响的研究. 西南农业大学学报, 2000, 22(5): 468-471.