土壤水盐运移的简化数学模型在水盐动态预报上的应用研究

对土壤水盐运移的确定性数学模型 ,采用数值模拟的简化法 ,实现对方程的求解。并引入水分运动原理、质量守恒原理 ,根据地下水、土壤水盐运动的特点 ,建立土壤剖面含水量分布的概化模型和土壤盐储量的预报模型。以期从土壤水盐运动的机制出发 ,提出一种应用简化数值模拟方法来预报土壤水盐动态的途径。同时为适应大面积田间土壤盐分预报的特点 ,希望不通过方程的求解来达到应用简化数学模型实现水盐动态预报的目的。所建简化数学模型可为田间大面积土壤水盐动态预测预报提供参考     

Field compaction at different soil-water status: effects on pore size distribution and soil water characteristics of a Rhodic Ferralsol in Western Cuba

The level of compaction induced on cultivated fields through trafficking is strongly influenced by the prevailing soil-water status and, depending on the attendant soil degradation, vital soil hydraulic processes could be affected. Therefore, understanding the relationship between field soil-water status and the corresponding level of induced compaction for a given load is considered an imperative step toward a better control of the occurrence of traffic-induced field soil compaction. Pore size distribution, a fundamental and highly degradable soil property, was measured in a Rhodic Ferralsol, the most productive and extensively distributed soil in Western Cuba, to study the effects of three levels of soil compaction on soil water characteristic parameters. Soil bulk density and cone penetration index were used to measure compaction levels established by seven passes of a 10 Mg tractor at three soil-water statuses corresponding to the plastic (Fs), friable (Fc) and relatively dry soil (Ds) consistency states. Pore size distribution calculated from soil water characteristic curves was classified into three pore size categories on the basis of their hydraulic functioning: >50 μm (f_>50 μm), 50–0.5 μm (f_{50–0.5 μm}) and <0.5 μm (f_<0.5 μm). The greatest compaction levels were attained in the Fs and Fc soil water treatments, and a significant contribution to compaction was attributed to the existing soil water states under which the soil compaction was accomplished. Average cone index (CI) values in the range of 2.93–3.70 MPa reflected the accumulation of f_<0.5 μm pores, and incurred severe reductions in the volume of f_>50 μm pores in the Fs and Fc treatments, while an average CI value of 1.69 MPa indicated increments in the volume of f_{50–0.5 μm} in the Ds treatment. Despite the differential effects of soil compaction on the distribution of the different pore size categories, soil total porosity (f_Total) was not effective in reflecting treatment effects. Soil water desorption at the soil water potentials evaluated (0.0 to −15,000 cm H₂O) was adversely affected in the f_<0.5 μm dominated treatments; strong soil water retention was observed with the predominance of f_<0.5 μm, as was confirmed by the high water content at plant wilting point. Based on these findings, the use of field capacity water content as the upper limit of plant available soil water was therefore considered inappropriate for compacted soils.     

河北省曲周盐渍化地区微咸水灌溉对土壤环境效应的影响

在田间条件下，利用微咸水和淡水对河北省曲周盐渍化地区冬小麦进行灌溉试验，对冬小麦耗水量及其构成以及土壤环境效应等方面进行了研究和分析。两年的研究结果表明在小麦生长季灌溉过多，不利于作物根系深扎，不能充分利用土壤水分，造成水资源的浪费。利用微咸水进行灌溉增加了土壤盐分，使土地质量有着潜在恶化的趋势；在小麦收获时土壤表层溶液电导率可达10 dS/m左右，如不采取适当的田间管理措施，土壤盐分将危害下一季作物生长。如合理利用，可充分发挥此地区地下浅层微咸水资源的生产潜力，可缓解该地区的水资源紧张，促进农业发展；但微咸水灌溉的长期土壤环境效应需进一步研究。     

土壤侵蚀与土壤肥力

对土壤侵蚀与土壤肥力概念进行了阐述,分析了两者之间的关系,指出土壤侵蚀与土壤肥力之间的作用是相互的,侵蚀造成土壤肥力的丧失,而土壤肥力的丧失反过来又加剧侵蚀作用的加强.在此基础上,提出了治理土壤侵蚀和培育土壤肥力时应注意的问题与治理方法.     

黄土高原南部梯田土壤水分环境效应研究

水平梯田是控制坡耕地水土流失和实现旱作区农业高产与稳产的根本措施之一。通过研究发现,在黄土残塬沟壑区的泥河沟流域,梯田具有比较明显的蓄水、保水作用。距田埂愈近,越靠近外部,越接近土壤表层,土壤湿度越小,土壤愈干旱,越近里面,且越向下,土壤湿度越大。     

伊朗西部不同土地利用方式下钙质土壤疏水性研究

Soil wettability and water repellency, two important soil physical properties, play an important role in water retention and water conductivity in arid and semi-arid regions. To date, there is a lack of information on soil water repellency in calcareous soils of western lran. In this study, soil water repellency and its affecting factors were studied using 20 soil series collected from Hamadan Province~ western Iran. The effects of soil properties including organic carbon content （SOC）, total nitrogen （TN）, C：N ratio, texture, CaCO3 content, and both fungal and bacterial activities on water repellency were investigated using air-dried, oven-dried and heated soil samples. Water repellency index （WRI） was determined using the short-time sorptivity （water/ethanol） method. To distinguish the actual effects of SOC, a set of soil samples were heated at 300 ~C to remove SOC and then WRI was measured on the heated samples. Relative water repellency index （RWRI） was defined as the change of WRI due to heating relative to the oven-dry WRI value. Results of the WRI values showed that the soils were sub-critically water-repellent. Pasture soils had higher WRI values compared to tilled soils, resulting from high SOC and TN, and high activities of bacteria and fungi. It was observed that SOC, TN, fungal activity, and SOC：clay ratio had significant positive impacts on WRI. Strong positive correlations of RWRI with SOC, TN and fungal activity were also observed. Pedotransfer functions derived for predicting WRI showed that the WRI values had an increasing trend with the increases in fungal activity, salinity, alkalinity and fine clay content, but showed a decreasing trend with increasing bacterial activity.     

基于物质平衡原理的贝类循环水养殖系统的设计与试验

为恢复和保护濒危淡水贝类资源,该文根据物质平衡原理,以具有代表性的淡水彩虹贝类为研究对象,设计并构建了一套小型的室内淡水彩虹贝循环水养殖系统,该系统由养殖池、生物过滤器、蓄水池、循环水泵、充氧系统和自动投饵装置等环节组成。并在该循环水系统中对钩介幼虫2日龄的彩虹贝幼贝进行了为期60 d的养殖(2011年6月21日到2011年8月20日),整个养殖周期内,彩虹贝幼贝养殖系统环境稳定,水质稳定良好,彩虹贝幼贝壳长日增长量为15.2μm/d,彩虹贝幼贝的最大相对增长率发生在第40天到第50天,其相对生长率为32.4%,和之前池塘流水、跑道式等养殖模式相比,该循环水系统养殖的彩虹贝幼贝获得了更高的生长率。该研究可为淡水贝类的人工繁育和养殖提供参考。     

Effects of Zeolite on Soil Nutrients and Growth of Barley Following Irrigation with Saline Water

ABSTRACT

Soil salinity is a major abiotic factor limiting crop production but an amendment with synthetic zeolite may mitigate effects of salinity stress on plants. The objective of the study was to determine the effects of zeolite on soil properties and growth of barley irrigated with diluted seawater. Barley was raised on a sand dune soil treated with calcium type zeolite at the rate of 1 and 5% and irrigated every alternate day with seawater diluted to electrical conductivity (EC) levels of 3 and 16 dS m^?1. Irrigation with 16 dS m^?1 saline water significantly suppressed plant height by 25%, leaf area by 44% and dry weight by 60%. However, a substantial increase in plant biomass of salt stressed barley was observed in zeolite-amended treatments. The application of zeolite also enhanced water and salt holding capacity of soil. Post-harvest soil analysis showed high concentrations of calcium (Ca^{2 +}), magnesium (Mg^{2 +}), sodium (Na⁺), and potassium (K⁺) due to saline water especially in the upper soil layer but concentrations were lower in soils treated with zeolite. Zeolite application at 5% increased Ca^{2 +} concentration in salt stressed plants; concentrations of trace elements were also increased by 19% for iron (Fe^{2 +}) and 10% for manganese (Mn^{2 +}). The overall results indicated that soil amendment with zeolite could effectively ameliorate salinity stress and improve nutrient balance in a sandy soil.     

Effects of deficit irrigation on tomato and eggplant and their infection with the root-knot nematode under controlled environmental conditions

Deficit irrigation has been widely investigated as a valuable strategy for dry regions where water is the limiting factor in crop cultivation. Soil moisture can be one of the important factors that influence root-knot nematode (RKN) disease development. To determine how different levels of irrigation can affect disease development, irrigation regimes ranging from 20% to full field capacity (FC) were applied to tomato and eggplant plants inoculated with Meloidogyne javanica (M. javanica) under controlled conditions. In addition, in vitro bioassays were done to evaluate the effect of water potential and soil moisture content on M. javanica viability in the soil and reproduction on plant hosts. The relative egg hatching percentage decreased significantly with decreasing water potential from –0.1 to –1 MPa. The use of 80% irrigation level caused minor reductions in growth but significantly reduced nematode infection load. Nematode infection was reduced even further at lower levels of irrigation, however this also led to marked reductions in fresh and dry weights of the tomato and eggplants. Therefore, deficit irrigation could be used at a rate of 80% or 60% of FC to increase water use efficiency and reduce the level of RKN (M. javanica) infection without greatly reducing the growth performance of tomato and eggplant crops.     

土壤含水率监测位置对温室滴灌番茄耗水量估算的影响

土壤水分传感器埋设位置的选择是局部灌溉条件下获得作物根区代表性土壤含水率数据,从而制定滴灌灌溉制度的关键。本文以日光温室滴灌番茄为对象,研究滴灌线源土壤湿润体内含水率分布状况,通过对比距滴灌带不同位置处土壤含水率监测结果估算番茄耗水量的差异,探讨土壤含水率监测的合理位置。结果表明,番茄生育期内14~25 mm的灌水定额主要用于增加0~40 cm土层的土壤含水率,湿润体内日平均土壤含水率分布在75%~100%田间持水率。作物生育期内连续多次滴灌条件下,沿滴灌带单个灌水器形成的湿润土体会充分叠加,形成近似均匀的土壤含水率带状分布,且作物生育期内沿深度方向0~40 cm土层土壤含水率均值无显著性差异,距滴灌带不同水平距离的土壤含水率随时间的变化趋势具有同步特点,无明显的滞后性。以集中80%总根量的土壤深度作为滴灌番茄水分渗漏下界面时,14~25 mm的灌水定额会导致深层渗漏,且深层渗漏量表现出一定的空间变异性。番茄生育期内深层渗漏量约占灌水量的13%。距滴灌带不同位置处的番茄耗水量除在番茄苗期和开花座果期有较大差异外,其余生育阶段的差异均在10%以内。对温室滴灌番茄来说,滴灌高频少量的灌溉特征有利于维持作物根系层适宜的土壤水分状态,监测1个含水率剖面即可满足估算作物耗水量的要求。