{"title":"Soil hydraulic properties and field-scale hydrology as affected by land-management options","authors":"Atiqur Rahman, M. Amin","doi":"10.20961/stjssa.v20i1.70504","DOIUrl":null,"url":null,"abstract":"Recurring puddling for long-term rice cultivation forms a plow pan at a particular soil depth, which alters soil hydraulic properties, field-scale hydrology, and nutrient persistence in the soil. This experiment aimed to assess the impact of long-term rice cultivation on root-zone soil hydraulic properties and field-scale hydrology. Soil core samples were collected from four land management options namely, rice‒rice, non-rice, rice and non-rice, and field ridge, at two sites, one with loam and another with silt-loam soil. The soil cores were sampled for each 10 cm layer up to 100 cm depth from three locations of each rotation at both sites. Soil hydraulic parameters were estimated using a pedotransfer function based on the measured bulk density and soil texture. A mathematical model named HYDRUS-1D predicted infiltration, percolation, and surface runoff with the estimated hydraulic properties for three extreme rainfall events, i.e., 3.33, 5, and 6.66 cm hr-1, during a 3-hour period. A plow pan was found at 20–30 cm soil depth for all the land management options but not for the field ridge. The plow pan of the rice‒rice rotation had the highest bulk density (1.53 g cm-3) and the lowest hydraulic conductivity (17.56 cm day-1). However, the top 10 cm soil layer in the rice–rice field had the lowest bulk density (0.93 g cm-3). At both sites, the field ridge had higher infiltration and percolation and lower runoff than other rotations. The study reveals that the field-ridge area of a rice field can be the main water loss pathway. Phosphorus concentration in the rice-rice rotation decreased from 7.7 mg kg-1 in the 10-cm soil layer to 2.49 mg kg-1 in the 100-cm layer. These findings will facilitate making better water management decisions.","PeriodicalId":36463,"journal":{"name":"Sains Tanah","volume":null,"pages":null},"PeriodicalIF":0.5000,"publicationDate":"2023-06-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Sains Tanah","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.20961/stjssa.v20i1.70504","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"AGRONOMY","Score":null,"Total":0}
引用次数: 0
Abstract
Recurring puddling for long-term rice cultivation forms a plow pan at a particular soil depth, which alters soil hydraulic properties, field-scale hydrology, and nutrient persistence in the soil. This experiment aimed to assess the impact of long-term rice cultivation on root-zone soil hydraulic properties and field-scale hydrology. Soil core samples were collected from four land management options namely, rice‒rice, non-rice, rice and non-rice, and field ridge, at two sites, one with loam and another with silt-loam soil. The soil cores were sampled for each 10 cm layer up to 100 cm depth from three locations of each rotation at both sites. Soil hydraulic parameters were estimated using a pedotransfer function based on the measured bulk density and soil texture. A mathematical model named HYDRUS-1D predicted infiltration, percolation, and surface runoff with the estimated hydraulic properties for three extreme rainfall events, i.e., 3.33, 5, and 6.66 cm hr-1, during a 3-hour period. A plow pan was found at 20–30 cm soil depth for all the land management options but not for the field ridge. The plow pan of the rice‒rice rotation had the highest bulk density (1.53 g cm-3) and the lowest hydraulic conductivity (17.56 cm day-1). However, the top 10 cm soil layer in the rice–rice field had the lowest bulk density (0.93 g cm-3). At both sites, the field ridge had higher infiltration and percolation and lower runoff than other rotations. The study reveals that the field-ridge area of a rice field can be the main water loss pathway. Phosphorus concentration in the rice-rice rotation decreased from 7.7 mg kg-1 in the 10-cm soil layer to 2.49 mg kg-1 in the 100-cm layer. These findings will facilitate making better water management decisions.
长期水稻种植的反复灌水在特定的土壤深度形成犁盘,这改变了土壤的水力特性、田间尺度的水文和土壤中的养分持久性。本试验旨在评估水稻长期栽培对根区土壤水力特性和田间水文的影响。土壤核心样本采集于四个土地管理方案,即水稻-水稻、非水稻、水稻-非水稻和田埂,两个地点,一个是壤土,另一个是粉砂壤土。在两个地点的每个轮作的三个位置对每10厘米至100厘米深度的土壤岩心进行采样。利用基于实测容重和土壤质地的土壤传递函数估计土壤水力参数。一个名为HYDRUS-1D的数学模型预测了3小时内3个极端降雨事件(即3.33、5和6.66 cm / h -1)的入渗、渗透和地表径流。所有土地管理方案都在20-30 cm土壤深度处发现了一个犁盘,但没有用于田脊。稻稻轮作的犁盘容重最高(1.53 g cm-3),水导率最低(17.56 cm d -1)。而水稻-稻田的前10 cm土层容重最低,为0.93 g cm-3。在这两个地点,田脊的入渗和渗漏均高于其他轮作,径流则低于其他轮作。研究表明,稻田的田埂区可能是主要的水分流失通道。水稻-水稻轮作的磷浓度从10 cm土层的7.7 mg kg-1下降到100 cm土层的2.49 mg kg-1。这些发现将有助于做出更好的水管理决策。