Salt-Water Dynamics in Soils: Ⅰ. Salt-Water Dynamics in Unsaturated Soils Under Stable Evaporation Condition

A long term simulation test on salt-water dynamics in unsaturated soils with different groundwater depths and soil texture profiles under stable evaporation condition was conducted.Salinity sensors and tensiometers were used to monitor salt and water variation in soils.The experiment revealed that in the process of fresh groundwater moving upwards by capillary rise in the column,the salts in subsoil were brought upwards and accumulated in the surface soil,and consequently the salinization of surface soil took place.The rate of salt accumulation is determined mainly by the volume of capillary water flow and the conditions of salts contained in the soil profile.Water flux in soils decreased obviously when groundwater depths fell below 1.5m.When there was an interbedded clay layer 30cm in thickness in the silty loam soil profile or a clay layer 100cm in thickness at the top layer,the water flux was 3-5 times less than in the soil profile of homogeneous silty loam soil.Therefore,the rate of salt accumulation was decreased and the effect of variation of groundwater depth on the water flux in soils was weakened comparatively.If there was precipitation or irrigation supplying water to the soil,the groundwater could rarely take a direct part in the process of salt accumulation in surface soil,especially,in soil profiles with an interbedded stratum or a clayey surface soil layer.     

蒸发条件下粘土层对土壤水和溶质运移影响的模拟

以土壤水和溶质运移的动力学原理为基础 ,采用数值模拟方法 ,研究了在浅层地下水和蒸发条件下含有粘土层土壤的水和Cl-的运移状况 ,重点探讨了两种粘土的层位和层厚对水和Cl-运移影响的差别及原因。研究结果表明 ,粘土层对土壤的水和溶质运移影响的程度 ,与层状土壤中该粘土及其组合土壤的水力学性质有关。本文模拟的重粘土 (简称Y粘土 )与轻壤土所组成的层状土壤 ,其基本情况为 ,随粘土层层位的升高和层厚加大 ,土壤水分蒸发和地下水补给速率降低 ,Cl-积累减少。而轻粘土 (简称R粘土 )与轻壤土所组成的层状土壤 ,由于它们的导水率曲线在压力水头h约 - 10 0 0cm处相交 ,当h低于此值时 ,R粘土的导水率就大于轻壤土的。因此 ,蒸发、补给速率和Cl-积累强度出现以顶位最高 ,甚至高于均质轻壤土 ,其次为底位 ,最低为中部层位的现象。在蒸发条件下Cl-在剖面中的积聚部位主要是土表。粘土层的存在 ,起到了阻滞作用 ,而阻滞程度则与该粘土水力学性质、层位、厚度和地下水埋深有关     

Research on the Influence of Water Vapor Diffusion and Evaporation on Water and Heat Transfer in Frozen Soil

Considering the model that the hydrothermal coupling moving rule of the seasonal frozen soil under freezing and thawing effect, a research was made that how deep we bury and the soil texture are to effect the rule of the diffusion and evaporation of water vapor. By monitoring the moisture content and temperature of the profile of the continuous freezing and thawing soil in region named Xiaotangshan mountain in Beijing and using the hydrothermal coupling moving model, the water transferring rule of clay and sandy loam in different depth that we buried was summarized. Many long-term field experiments showed that when frozen layer buried in a deep way was in a frozen state, the interactive movement of the water in the soil was not active and evaporated slowly. The average value of the water evaporation of clay was about 0.51 mm/day approximately and the situation of the sandy loam soil was 1.24 mm/day. By qualitative analyzing and observation, the less we buried (less than 0.8 m), the ice in the frozen soil layer got more. Besides, the density of the frozen soil layer went higher but the water barely diffused. On the contrary, with the increase of the depth, the diffusion went stronger and stronger due to the contact between the soil and the groundwater. In addition, according to the different soil texture detections, the diameter of soil particle has great influence on the diffusion of the water vapor in the soil. The diffusion rate of the water vapor in the sandy loam soil was twice than that of in clay. Other field water coupling experiments showed that, the soil moisture content was greater, soil freezing period density was larger, and soil water infiltration rate was zero. Soil evaporation was gradually decreased with the increasing of groundwater depth, and the size of soil particle would have a more obvious effect on soil water vapor diffusion and evaporation. Our research results can provide scientific basis for the buried area where contains groundwater to keep moisture in the winter and the resource content of the groundwater in Beijing and the locations in the same latitude of Beijing. This paper’s purpose was to research the law of water vapor diffusion and evaporation, with different soil texture and burial depth, so it can verify the coupled model of seasonal frozen soil water and heat migration.     

不同质地裸土潜水蒸发估算方法

为定量分析裸土区潜水蒸发与水面蒸发的关系,该文通过自制试验装置,对粗砂、细砂、壤土和砂土4种质地土壤开展了二者之间相关关系的试验研究。结果表明:相同条件下,不同土壤质地的潜水蒸发与水面蒸发量不相等,二者之间存在一个折算系数,除粗砂外,细砂、壤土和砂土的折算系数均大于1,二者表现出较强的线性相关性,基于该相关性,建立了数学关系表达式。与实测数据的对比分析表明,若用水面蒸发强度代替潜水蒸发,相对误差达-17.79%,这将不可避免地影响到潜水蒸发计算结果的精度;而通过二者相关关系建立的折算系数法,可将相对误差减小至-1.94%,有效提高了潜水蒸发计算结果的可靠度。     

Salt-Water Dynamics in Soils: II. Effect of Precipitation on Salt-Water Dynamics

Through a simulation test carried out with soil columns (61.8cm in diameter),the effect of precipitation on salt-water dynamics in soils was studied by in-situ monitoring of salt-water dynamics using soil salinity sensors and tensioneters.The results show that in the profile of whole silty loam soil,the surface runoff volume due to precipitation and the salt-leaching role of infiltrated precipitation increased with the depth of ground water;and in the profile with an intercalated bed of clay or with a thick upper layer of clay,the amount of surface runoff was greater but the salt-leaching role of precipitation was smaller than those in the profile of whole silty loam soil.In case of soil water being supplemented by precipitation,the evaporation of groundwater in the soil columns reduced,resulting in a great decline of salt accumulation from soil profile to surface soil.The effect of precipitation on the water regime of soil profile was performed via both water infiltration and water pressure transfer.The direct infiltration depth of precipitation was less than 1m in general,but water pressure transfer could go up to groundwater surface directly.     

水平微润灌湿润体HYDRUS-2D模拟及其影响因素分析

为探索土壤质地、初始含水率、压力水头和埋深对水平微润灌土壤湿润体特性的影响机理,利用试验数据验证了水平微润灌HYDRUS-2 D模拟结果的可靠性,模拟值与实测值非常吻合。在此基础上,模拟研究了3种土壤质地(砂壤土、壤土、粉壤土)以及壤土中不同初始含水率(0.085、0.106、0.130 cm~3/cm~3)、压力水头(0.6、1.2、1.8 m)和埋深(20、30、40 cm)条件下土壤湿润体动态变化规律。结果表明:土壤湿润锋运移距离皆符合垂直向下水平方向垂直向上的规律,湿润体在形状上差异不大,土壤含水率等值线均为近似"同心圆";土壤质地对湿润体特性有显著影响,土壤质地越黏重,湿润锋运移速率越慢,湿润体体积越小,土壤含水率等值线越密集,其"圆心"越靠近微润管,灌水结束时,壤土和砂壤土湿润体体积分别是粉壤土的1.3倍和2.5倍;在确定的土壤质地条件下,初始含水率和压力水头对湿润体特性有较大影响,湿润锋运移距离及湿润体体积均随土壤初始含水率、压力水头的增大而增大,初始含水率为0.106和0.130 cm~3/cm~3的湿润体体积分别是0.085 cm~3/cm~3的1.2倍和1.5倍,压力水头为1.2和1.8 m的湿润体体积分别是0.6 m的1.6倍和2.2倍;微润管埋深对湿润体分布位置有显著影响,埋深较浅时,湿润锋容易到达地表,埋深较深时,土壤湿润体随埋深下移而同步下移。     

基于颗粒模型的风积砂层降雨入渗深度计算及验证

为了研究沙漠干旱区降雨对砂层非饱和带水分的贡献,该文对风积砂层水分入渗过程中的水分存在形式和运移机理进行了理论和力学分析。通过以触点水为主要储水单元的立方布局颗粒模型推导出水分入渗过程中湿润深度的解析表达式,并进行验证。物理和力学分析表明,砂颗粒表面很难形成较厚的薄膜水,砂层非饱和带水分大部分以触点水的形式存在。模型计算结果表明,水分入渗的湿润深度与入渗水量和触点水湿润角有关。模型验证表明,水分入渗湿润深度的解析表达式在风积砂层入渗深度计算中具有一定的适用性,但触点水湿润角与砂颗粒粒径的函数关系还有待进一步研究当设定触点水湿润角为π/4时,比例常数为11.5。该研究可为干旱区农业规划提供依据。     

土壤盐－水动力学: V.土壤剖面盐平衡

Salt balance in simulated soil coulumns was calculated on the basis of a large amount of long term observation data.The results showed that under the climate conditions of semi-arid region of the Huang-Huai-Hai Plain,the soils in the columns were under salt accumulation conditions when the groundwater depth was controlled at less than 2.0m,and under desalinization conditions when at larger than 2.5m.In the soil columns with clay soil and silty loam soil intercalated with a clay layer,the amount of salt accumulated was far less than that in the soil column with silty loam soil throughout the whole profile.Under no irriagtion conditions crop planting may increase groundwater evaporation and hence salt accumulation in soil,making the soil columns under desalinization be under salt accumulation conditions.     

夹砂层土体构型毛管水上升的实验研究

针对西北地区土壤剖面多呈层状和春季强烈返盐季节土壤多处于裸露状态的特点，通过室内土柱实验，研究了有地下水位条件下夹砂层剖面的土壤蒸发问题。结果表明，砂层会影响毛管水上升的高度和速度，毛管水到达土表的时间随砂层厚度的增加、层位的升高以及级配的变差而延长，但砂层级配对于水分的阻滞作用最大。砂层影响各层土壤含水量的分布，在水分达到平衡状态时，砂层以下土壤含水量大于均质土，而砂层以上土壤含水量则小于或近似于均质土。砂层能明显降低地下水的蒸发量，但夹砂层土柱的蒸发量随砂层厚度的增加而降低，而表砂层土柱的蒸发量则随砂层厚度的增加而增强。在蒸发阶段，砂层层位的作用表现更为显著。     

施肥时机对土壤水氮运移转化规律的影响

为揭示不同施肥时机（全过程、前1/2和后1/2入渗水量施肥）下土壤水氮运移转化规律,以砂壤土和黏壤土质地的一维垂直肥液（尿素）入渗试验为基础,重点分析不同施肥时机下土壤水氮分布与再分布过程中的运移转化规律,并量化比较其对土壤中氮素含量的影响。结果表明,施肥时机对土壤累积入渗量和湿润体中水分分布影响微小,但对不同形态氮素运移转化影响显著;砂壤土和黏壤土入渗结束时刻,全过程和后1/2入渗水量施肥时,其尿素态氮、铵态氮（NH₄⁺—N）和硝态氮（NO₃^-—N）含量均随土层深度增大而减小;前1/2入渗水量施肥时,尿素态氮和NO₃^-—N含量在湿润体边缘累积,NH₄⁺—N呈先增大后减小趋势,且主要分布在5—25 cm土层;再分布阶段,全过程和后1/2入渗水量施肥时,砂壤土和黏壤土中尿素态氮分别在再分布3天和5天时基本水解完成,同时NH₄⁺—N含量达到峰值,NO₃^-—N含量再分布10天内未出现下降趋势;前1/2入渗水量施肥时,尿素态氮再分布10天时基本水解完成,NH₄⁺—N含量再分布5~10天达到峰值,NO₃^-—N含量则呈先增加后减小趋势;后1/2入渗水量和全过程施肥条件下,砂壤土和黏壤土再分布10天时0—40 cm土层中NH₄⁺—N和NO₃^-—N含量均大于前1/2入渗水量施肥,说明其氮素潜在利用效率高,故推荐畦（沟）灌合理施肥时机为后1/2入渗水量或全过程施肥。研究结果可为农田畦（沟）灌施肥系统的设计和管理提供理论基础和技术支撑。