«Previous Article|Table of Contents|Next Article»

《北方园艺》[ISSN:1001-0009/CN:23-1247/S]

Issue:

2022年13

Page:

96-104

Research Field:

Publishing date:

Info

Title:

Root System and Soil Water Distribution of Kiwifruit Tree Under Water Accumulation and Impermeability Control Technology in Guanzhong Area

Author(s):

ZOU Heng1; XIE Yongsheng1; 2; LUO Han1; 2; CHEN Dongkai1; SHENG Yuzhang1; LI Zhen1

(1.Institute of Soil and Water Conservation，Northwest Agriculture & Forestry University，Yangling,Shaanxi 712100;2.Institute of Soil and Water Conservation，Ministry of Water Resources，Chinese Academy of Sciences，Yangling，Shaanxi 712100)

Keywords:

soil water content; water accumulation and impermeability measures; root system; kiwifruit orchard; Guanzhong Area

PACS:

-

DOI:

10.11937/bfyy.20215166

Abstract:

Taking nine-year-old kiwifruit garden in Guanzhong Area as research object,the soil water content of 0-200 cm profile and the dry weight density of roots in 0-100 cm soil layer was researched，the effects of water accumulation and impermeability measures on the growth and development of kiwifruit roots and the spatial distribution characteristics of soil water were understood,in order to provide reference for the ecological regulation technology of kiwifruit orchard in viscous soil in Guanzhong Area.The results showed that different water accumulation and impermeability measures could cause significant changes in soil water content from 0-200 cm.Treatment Ⅲ (backfilling garden soil with water accumulation and seepage prevention tank + fly ash + chemical fertilizer + organic fertilizer) and Ⅳ (backfilling garden soil with water accumulation and seepage prevention tank + fly ash + chemical fertilizer + distiller′s grains and vinegar grains) eliminated the soil dry layer between 40-100 cm in the experimental orchard in the dry season.After the rainy season，treatment Ⅰ (garden soil backfilled by water accumulation and anti infiltration tank)，Ⅱ (garden soil backfilled by water accumulation and anti infiltration tank + chemical fertilizer)，Ⅲ and Ⅳ significantly increased the soil water content of 0-100 cm.The water content of treatment Ⅰ，Ⅱ，Ⅲ and Ⅳ in this area increased by 40.04%，50.22%，45.02% and 58.30% compared with CK (blank treatment).Affected by the water accumulation and impermeability measures，the root dry mass 〖JP2〗density under treatment Ⅲ at 0-100 cm away from the trunk between rows was the largest (13 208.5 g?m-3)，followed by Ⅰ (4 618.8 g?m-3)，Ⅱ (3 289.14 g?m-3) and Ⅳ (1 640.52 g?m-3)，and CK was the smallest (1 326.04 g?m-3).The water accumulation and impermeability measures could significantly change the distribution of soil water in different soil layers，reduce or even eliminate the soil dry layer，and promote the biomass accumulation of fruit tree roots in wet soil layers.In conclusion，the effect of treatment Ⅲ was better than that of Ⅱ，Ⅰ and Ⅳ.

References:

[1]李百云,刘旭峰,金会翠，等.陕西眉县部分猕猴桃园土壤主要养分状况分析[J].西北农业学报，2008，17(3):215-218.[2]张计育，莫正海，黄胜男，等.21世纪以来世界猕猴桃产业发展以及中国猕猴桃贸易与国际竞争力分析[J].中国农学通报，2014，30(23):48-55.[3]张福平，高张，李肖娟，等.基于最小数据集的周至县猕猴桃园地土壤质量评价[J].生态与农村环境学报，2019，35(1):69-75.[4]雷宝佳，杨联安，张林森，等.猕猴桃果园土壤养分空间变异性分析:以陕西周至县为例[J].西北大学学报(自然科学版)，2015，45(2):323-326.[5]黄龙.半干旱区猕猴桃树滴灌耗水特性与灌溉制度试验研究[D].西安:西安理工大学，2017.[6]董军，赵勇胜，杨继东,等.沸石改性天然粘土防渗层性能研究[J].环境科学与技术，2005，28(4):92-94,120.[7]索改弟，谢永生，田飞，等.土壤中人工防渗层的水分特征[J].应用生态学报，2014，25(9):2569-2575.[8]金波，王延平，穆艳，等.山地果园集雨-壤中防渗对水分入渗、分布和利用率的影响[J].应用生态学报，2018，29(5):1559-1568.[9]武琳，郑永红，张治国，等.粉煤灰用作土壤改良剂的养分和污染风险评价[J].环境科学与技术，2020，43(9):219-227.[10]揣峻峰.渭北果园生态系统调控途径和技术研究[D].杨凌:西北农林科技大学，2013.[11]蔡铭阳.渭北果园土壤生态系统水肥高效利用新技术研究[D].杨凌:西北农林科技大学，2017.[12]MA L H,LIU X L，WANG Y K，et al.Effects of drip irrigation on deep root distribution，rooting depth，and soil water profile of jujube in a semiarid region[J].Plant and Soil，2013，373(1/2):995-1006.[13]TANASESCU N，PALTINEANU C.Root distribution of apple tree under various irrigation systems within the hilly region of Romania[J].International Agrophysics，2004，18(2):175.[14]SOKALSKA D I，HAMAN D Z，SZEWCZUK A，et al.Spatial root distribution of mature apple trees under drip irrigation system[J].Agricultural Water Management，2008,96(6):917-924.[15]SONG X L，GAO X D，WU P T，et al.Drought responses of profile plant-available water and fine-root distributions in apple (Malus pumila Mill.) orchards in a loessial，semi-arid，hilly area of China[J].Science of the Total Environment，2020,723:137739.[16]孙蕾.渭北地区果园土壤质量演变趋势[D].杨凌:西北农林科技大学，2010.[17]茹豪，张建军，张琦，等.晋西黄土区雨养果园土壤水分动态及对降雨的响应[J].水土保持学报，2014，28(1):36-42.[18]索改弟，谢永生，揣峻峰,等.苹果园地表起垄微聚流技术调控下土壤水分的时空分布[J].生态学杂志，2013，32(9):2354-2361.[19]段晨宇.黄土高原植被对土壤储水量和土壤干层的影响[D].杨凌:西北农林科技大学，2017.[20]孙文泰，刘兴禄，董铁，等.陇东旱塬苹果园不同覆盖措施对土壤性状、根系分布和果实品质的影响[J].果树学报，2015，32(5):841-851.[21]康博文，刘建军，孙建华，等.陕北毛乌素沙漠黑沙蒿根系分布特征研究[J].水土保持研究，2010，17(4):119-123.[21]GONG D Z，KANG S Z，ZHANG L，et al.A two-dimensional model of root water uptake for single apple trees and its verification with sap flow and soil water content measurements[J].Agricultural Water Management，2005，83(1):119-129.[23]宋小林，吴普特，赵西宁，等.黄土高原肥水坑施技术下苹果树根系及土壤水分布[J].农业工程学报，2016，32(7):121-128.[24]〖JP2〗VALENTINE T A，HALLETT P D，BINNIE K，et al.Soil strength and macropore volume limit root elongation rates in many UK agricultural soils[J].Annal of Botany，2012,110:259-270.[25]BENGOUGH A G，MCKENZIE B M，HALLETT P D，et al.Root elongation，water stress，and mechanical impedance:A review of limiting stresses and beneficial root tip traits[J].Journal of Experimental Botany，2011，62(1):59-68.[26]高登涛，郭景南，魏志峰，等.果园地面覆盖对土壤质量和苹果生长发育的影响[J].果树学报，2010，27(5):770-777.

Memo

Memo:

-

Common functions

Last Update: 2022-08-31