土壤动物群落生态学与土壤微生态环境的关系

主要综述了国内外蚯蚓种群、捕食性线虫、蚂蚁、跳虫、螨类等土壤动物与土壤理化性质的关系,以及蚯蚓、白蚁、蜗牛、线虫等土壤动物与土壤酶活性的相关性研究;提出了该学科今后的研究趋势。该学科未来要融合土壤动物和整个农林生态系统的研究为一体,把农林的土壤动物群落生态学及其与土壤微生态环境关系结合起来,耦合土壤动物与植物根系-根际微生态环境,链接农林土壤动物与土壤健康及其害虫生态调控,分析探究它们内在的联系和机制,加强立地调控措施,为森林健康和土壤健康提供科学基础资料。     

土壤微生物量和土壤呼吸对降雨的响应

本研究在北京门头沟龙凤岭水土保持科技示范园内进行,降雨前后连续测定土壤微生物量和土壤呼吸,探讨土壤微生物量和土壤呼吸对降雨的响应。结果表明：干旱的土壤降雨后土壤微生物量和土壤呼吸骤升随后逐渐衰减,第1场降雨后土壤微生物量碳、氮和土壤呼吸分别是干旱期的3.08、2.83、2.50倍,第2场降雨后土壤微生物量碳、氮和土壤呼吸分别是干旱期的1.08、1.63、1.68倍,降雨使土壤微生物量和土壤呼吸产生的激增效应仅持续1 d。第3场降雨量仅为0.40 mm,土壤微生物量和土壤呼吸增加的幅度不是很大。     

施肥与设施栽培措施对土壤微生物区系的影响

微生物肥料的施用能显著增加土壤中放线菌的数量，而降低细菌和霉菌的数量；施用有机肥对土壤微生物有较大的影响，其中，有机肥与无机肥，有机肥与生物肥配合施用的影响尤为明显，与对照相比，土壤中细菌数量分别增加109．8％和405．0％，放线菌数量分别增加320．3％和215．0％，而真菌数量分别降低44．0％和47．2％。大棚栽培条件下土壤微生物数量高于露地；在大棚中，种植年限长的土壤微生物数量低于种植年限短的。     

马尾松林地与玉米地土壤有机碳的分异研究

林农生态系统转化对土壤有机碳(SOC)组成和来源产生了较大的影响,但不同学者的结论仍然存在一定差异,且这一转化过程对土壤溶解性有机碳(DOC)的影响鲜有报道.基于这一背景,该研究在贵州中部区域选择马尾松(Pinus massoniana)林地和玉米(Zea mays L.)地土壤作为研究对象,通过对SOC和DOC含量和同位素组成的测定,分析林农生态系统转化前后土壤有机碳的分异.结果表明,在马尾松林地剖面中,SOC和DOC含量随剖面深度的变化幅度均大于玉米地土壤,DOC含量最大值出现在5～10 cm处;銼O13C和銬O13C随着土壤深度的加深有所偏正,但銬O13C在剖面中的变异远大于銼O13C,其极差分别为5.015‰和2.431‰;通过对比銬O13C和銼O13C的差异,说明其0～5 cm的DOC主要来源于新成枯枝落叶,而土体内部DOC则主要来自土壤腐殖类物质的转化.在玉米地剖面中,銼O13C和銬O13C随着土壤深度的加深有所偏负,但整个剖面中两值的差异较小,DOC主要来源于土壤腐殖类物质的转化;SOC来源于玉米植物体有机碳(C4-C)的比例介于2.55%～20.80%之间,随剖面层次的加深有降低趋势,但出现"之"字形反复;DOC中C4-C的比例在剖面0～40 cm间较为相近(25.94%～34.54%),40 cm以下则急剧下降(3.18%～15.65%).     

岩溶表层带土壤温度和含水率对呼吸作用的影响

全球环境变化对岩溶区的碳循环产生重要的影响,而土壤呼吸作用在全球环境变化的影响和反馈的过程中具有十分重要的作用。因此,以岩溶区的岩溶表层带为研究对象,研究了土壤呼吸作用与土壤温度和大气降水量之间的响应机理和内在联系。研究结果表明：岩溶表层带的土壤呼吸作用具有单峰型的季节性变化特征。洼地0~5、10~20 cm 的土壤呼吸速率在范围变化分别为82.58 mg· m-2· h-1至412.89、151.39 mg· m-2· h-1至523 mg· m-2· h-1,最大值出现在8月中旬。坡地0~5、10~20 cm的土壤呼吸速率在范围变化55.05 mg· m-2· h-1至412.89、137.63 mg· m-2· h-1至495.47 mg· m-2· h-1,最大值出现也在8月中旬。洼地的土壤呼吸作用相对强于坡地,主要是由于坡地土壤相对洼地土壤较薄并且容易被降水冲刷搬运。在大气降水量不成为限制土壤呼吸作用的因子下,土壤温度为主要控制土壤呼吸作用的因子。因此,该研究可为控制土壤呼吸作用缓和大气CO2的升高和温室效应应对策略,为国家固碳减排的科学决策提供理论依据。     

绿肥轮作对植烟土壤酶活性与微生物量碳和有机碳的影响

为探讨绿肥作物改良土壤的生态作用,试验以冬闲连作地为对照,在云南曲靖和晋宁烟草种植区,研究了小麦轮作收获后留根茬（20 cm左右）翻压后种植烟草（麦-烟）,紫花苕子收获后留根茬（30 cm左右）翻压后种植烟草（绿-烟）及豆类轮作（豆-烟）收获后根茬及秸秆全部移除地外种植烟草的4种轮作模式,结果表明：绿-烟和豆-烟复种模式下,植烟生长期内根区土壤酶活性（SEA）、土壤微生物量碳（SMBC）及土壤有机碳（SOC）均高于麦-烟复种及冬闲连作地,并且差异达显著或极显著水平;不同复种模式的SMBC、SOC及SMBC/SOC间呈显著相关性,对提高土壤SEA、SMBC与SOC质量分数影响为：绿-烟〉豆-烟〉麦-烟〉冬闲地。研究认为,SEA及SMBC/SOC可作为评价轮作模式影响烟地红壤质量变化的生物学指标。     

Impacts of land use conversion on soil properties and soil erodibility

Land use conversion can affect natural ecological processes such as surface runoff and erosion. Therefore, it has potential to change soil stability To investigate this process in depth, Iskalan creek catchment in the Black sea region, where excessive land use applications and erosion events have often occured, was selected as the study area. The objective was to determine the effects of land use conversion on soil properties, soil erodibility and the relationships among soil properties and some erodibility indices. Duplicate topsoil samples were taken by using steel cylinders at 100 different sampling points from three different land use types; 34 of them are in farmlands, 34 in rangelands and 32 in forestlands. Soil particle size distribution, loss of ignition, pH, electrical conductivity skeleton percentage and three erodibility indices were determined. Data were analysed by using Pearson correlation analysis (at 95% and 99% significance level), ANOVA and Tukey's test at 95 % significance level. According to study results, land use conversion affects some properties of soils significantly Loss of ignition of soils in forests was significantly higher than soils in farmlands and rangelands. Soil skeleton percentage in rangelands and farmlands were significantly different. The study results showed that there was significant difference between pH of soils in forests and farmlands (p < 0.05). Pearson correlation analysis results showed significant correlations among erodibility indices and certain soil properties such as clay and sand fraction of soils (p < 0.05 and p < 0.01). Topsoils of the study area were sensitive to erosion according to all three erodibility indices. The most sensitive soils were in farmlands.     

紫花苜蓿改良盐渍土对土壤微生物活性和养分含量的影响

为探讨干旱地区种植紫花苜蓿改良盐渍土对土壤微生物生物量及其活性和土壤养分的影响,选择河西走廊黑河流域国有临泽农场的草甸盐土荒地作为对照,研究了种植紫花苜蓿2、3、4年后的改土效果。结果表明：与CK相比,连续种植4年后,所测定的土壤化学性质和微生物化学性质指标都发生了极显著（P〈0.01）的有利变化,电导率下降5.96 mS.cm-1,pH下降0.25,有机碳增加1.50 g.kg-1,微生物生物量碳增加48.93 mg.kg-1,微生物熵上升0.43%,荧光素二乙酸酯水解率提高10.87μg.g-1.h-1,碱解氮增加17.37 mg.kg-1,速效磷增加2.87 mg.kg-1,速效钾增加44.93 mg.kg-1。相关分析表明,微生物生物量碳、微生物熵、荧光素二乙酸酯水解率、碱解氮、速效磷、速效钾与土壤有机碳之间极显著（P〈0.01）正相关,相关系数分别为0.86、0.80、0.87、0.85、0.79、0.80,而与电导率之间极显著（P〈0.01）负相关,相关系数分别为-0.83、-0.79、-0.84、-0.86、-0.88、-0.78。研究认为,种植紫花苜蓿对草甸盐土有显著的改良效果,电导率下降,有机碳含量提高,微生物活性增强,速效养分含量增加。     

华南红壤坡面侵蚀水动力学机制试验研究

华南红壤区是我国发生潜在水土流失危害的重点区域之一,红壤坡地的水土流失现象较为严重。华南红壤地区气候温暖,雨量丰沛,降雨特点通常表现为强度大、历时长,暴雨或大暴雨事件频发,因此暴雨驱动因子影响作用更为显著,研究探讨华南红壤坡面侵蚀过程及动力特征有着重要的现实意义。通过室内35场不同雨强（30、60、90、120、180、210、270 mm·h-1）、不同坡度（5°、10°、15°、20°、25°）的人工模拟降雨试验,研究了华南红壤侵蚀的水动力学机制。主要取得以下研究结果：（1）红壤坡面侵蚀水流的流态大部分均处于＂层流—缓流区＂,除平均流速随着模拟雨强的增加而增加外,其他水动力参数（坡面侵蚀水流的阻力、曼宁糙率、径流剪切力、以及水流功）均会受到雨强和坡度改变的影响,但是不呈现特定的函数关系,规律不明显;（2）从水动力学角度解析了红壤坡面水蚀过程,得出了相对水深和曼宁糙率系数两种水动力因子共同组成的复合水动力特征参数,可作为表征不同雨强及坡度下的坡面水蚀侵蚀产沙的特征水动力参数指标。     

施用营养型土壤改良剂对水稻产量和土壤肥力的效应

探讨了营养型土壤改良剂(简称改良剂)对水稻产量、土壤酸度、土壤养分、土壤肥力和土壤物理性能的效应。连续2年4造水稻试验结果表明,施用改良剂比对照稻谷产量增加8.6%~11.3%(平均10.3%),增产达极显著水平,并且有良好后效。施用土壤改良剂具有提高pH,降低活性Al,增加N、P、K有效养分和代换性K、Ca和Mg的效果。     

生物修复PAHs污染土壤对酶活性的影响

在PAHs污染土壤生物修复过程中,以黑麦草、苜蓿为修复植物,固定化微生物菌剂为外源微生物,通过盆栽实验研究了不同处理对土壤酶活性的影响,以及酶活性与PAHs的去除效果之间的相关性。结果表明,植物修复、微生物修复及两者联合修复均显著提高了土壤PAHs的去除效果,其中黑麦草和苜蓿与微生物菌剂联合修复效果分别达到37.57%和38.41%,比单独的植物修复和菌剂修复高出一倍左右。各种生物修复同时促进了土壤多酚氧化酶、脱氢酶及脲酶的活性,减少了过氧化氢酶活性。过氧化氢酶活性与多酚氧化酶活性呈显著负相关（P〈0.05）、而脲酶与多酚氧化酶显著正相关（P〈0.05）。进一步分析表明PAHs的去除率与脱氢酶活性极显著正相关（P〈0.01）,与多酚氧化酶活性呈显著正相关（P〈0.05）,与过氧化氢酶活性呈负相关（P=0.564）;因此,在PAHs污染土壤生物修复过程中,可以选择土壤脱氢酶活性和多酚氧化酶活性作为PAHs修复效率的微生态指示指标。     

Heavy metals and soil microbes

Heavy metal pollution is a global issue due to health risks associated with metal contamination. Although many metals are essential for life, they can be harmful to man, animal, plant and microorganisms at toxic levels. Occurrence of heavy metals in soil is mainly attributed to natural weathering of metal-rich parent material and anthropogenic activities such as industrial, mining, agricultural activities. Here we review the effect of soil microbes on the biosorption and bioavailability of heavy metals; the mechanisms of heavy metals sequestration by plant and microbes; and the effects of pollution on soil microbial diversity and activities. The major points are: anthropogenic activities constitute the major source of heavy metals in the environment. Soil chemistry is the major determinant of metal solubility, movement and availability in the soil. High levels of heavy metals in living tissues cause severe organ impairment, neurological disorders and eventual death. Elevated levels of heavy metals in soils decrease microbial population, diversity and activities. Nonetheless, certain soil microbes tolerate and use heavy metals in their systems; as such they are used for bioremediation of polluted soils. Soil microbes can be used for remediation of contaminated soils either directly or by making heavy metals bioavailable in the rhizosphere of plants. Such plants can accumulate 100 mg g^?1 Cd and As; 1000 mg g^?1 Co, Cu, Cr, Ni and 10,000 mg g^?1 Pb, Mn and Ni; and translocate metals to harvestable parts. Microbial activity changes soil physical properties such as soil structure and biochemical properties such as pH, soil redox state, soil enzymes that influence the solubility and bioavailability of heavy metals. The concept of ecological dose (ED₅₀) and lethal concentration (LC₅₀) was developed in response to the need to easily quantify the influence of pollutants on microbial-mediated ecological processes in various ecosystems.     

耕作方式对土壤微生物和土壤肥力的影响

通过2年田间定位试验,对比研究了免耕+秸秆覆盖、旋耕+秸秆覆盖和传统耕作:三种耕作方式对土壤温度、土壤呼吸速率、土壤微生物数量和土壤肥力状况的影响.结果表明:秸秆覆盖对地温的影响存在"双重效应";土壤温度、土壤呼吸速率和土壤微生物量碳三者之间存在凸面关系;秸秆还田后耕作措施对土壤0～10和10～20 cm的微生物数量的影响不同,但均能增加土壤微生物量;土壤微生物能够加快秸秆中的有机碳向土壤有机质的转化速率;土壤微生物量碳可以作为反映土壤生产力状况的重要生物学指标之一.     

土壤与酸的反应时间对土壤酸度及土壤溶液中铝离子形态分布的影响

用两种土壤研究土壤与酸的反应时间对土壤酸度及土壤溶液中铝离子形态分布的影响。结果表明,土壤溶液pH随反应时间增加而增加,安徽红壤pH的增幅大于江西红壤。在pH3.0的HNO3溶液中,土壤溶液中的总铝及Al3 均随反应时间增加而减少,而在pH3．5的HNO3溶液中,土壤溶液中总铝及Al－F络合物先随反应时间的增加而减小．然后又有所增加。     

Amazonian deforestation and soil biodiversity

Clearance and perturbation of Amazonian forests are one of the greatest threats to tropical biodiversity conservation of our times. A better understanding of how soil communities respond to Amazonian deforestation is crucially needed to inform policy interventions that effectively protect biodiversity and the essential ecosystem services it provides. We assessed the impact of deforestation and ecosystem conversion to arable land on Amazonian soil biodiversity through a meta-analysis. We analyzed 274 pairwise comparisons of soil biodiversity in Amazonian primary forests and sites under different stages of deforestation and land-use conversion: disturbed (wildfire and selective logging) and slash-and-burnt forests, pastures, and cropping systems. Overall, 60% and 51% of responses of soil macrofauna and microbial community attributes (i.e., abundance, biomass, richness, and diversity indexes) to deforestation were negative, respectively. We found few studies on mesofauna (e.g., microarthropods) and microfauna (e.g., protozoa and nematodes), so those groups could not be analyzed. Macrofauna abundance and biomass were more vulnerable to the displacement of forests by pastures than by agricultural fields, whereas microbes showed the opposite pattern. Effects of Amazonian deforestation on macrofauna were more detrimental at sites with mean annual precipitation >1900 mm, and higher losses of microbes occurred in highly acidic soils (pH < 4.5). Limited geographic coverage, omission of meso- and microfauna, and low taxonomic resolution were main factors impairing generalizations from the data set. Few studies assessed the impacts of within-forest disturbance (wildfires and selective logging) on soil species in Amazonia, where logging operations rapidly expand across public lands and more frequent severe dry seasons are increasing the prevalence of wildfires.     

土壤矿质氮和可矿化氮对当季作物的贡献

从土壤矿质氮-硝态氮和铵态氮、土壤可矿化氮3个指标研究了土壤剖面不同层次有效氮对作物吸氮的贡献.结果表明,不同指标反映土壤供氮能力状况不一.土壤硝态氮和土壤可矿化氮与作物吸氮有较好的相关关系,而土壤铵态氮与作物吸氮关系不密切.在深度120cm之上的土层的土壤可矿化氮对作物吸氮有较大的贡献.在考虑土壤供氮能力时,建议应该考虑120cm深层以上的土壤.     

Toward a complete soil C and N cycle: incorporating the soil fauna

Increasing pressures on ecosystems through global climate and other land-use changes require predictive models of their consequences for vital processes such as soil carbon and nitrogen cycling. These environmental changes will undoubtedly affect soil fauna. There is sufficient evidence that soil fauna have significant effects on all of the pools and fluxes in these cycles, and soil fauna mineralize more N than microbes in some habitats. It is therefore essential that their role in the C and N cycle be understood. Here we introduce a new framework that attempts to reconcile our current understanding of the role of soil fauna within the C and N cycle with biogeochemical models and soil food web models. Using a simple stoichiometric approach to integrate our understanding of N mineralization and immobilization with the C:N ratio of substrates and faunal life history characteristics, as used in food web studies, we consider two mechanisms through which soil fauna can directly affect N cycling. First, fauna that are efficient assimilators of C and that have prey with similar C:N ratios as themselves, are likely to contribute directly to the mineral N pool. Second, fauna that are inefficient assimilators of C and that have prey with higher C:N ratios than themselves are likely to contribute most to the dissolved organic matter (DOM) pool. Different groups of fauna are likely to contribute to these two pathways. Protists and bacteria-feeding nematodes are more likely to be important for N mineralization through grazing on microbial biomass, while the effects of enchytraeids and fungal-feeding microarthropods are most likely to be important for DOM production. The model is consistent with experimental evidence and, despite its simplicity, provides a new framework in which the effects of soil fauna on pools and fluxes can be understood. Further, the model highlights our gaps in knowledge, not only for effects of soil fauna on processes, but also for understanding of the soil C and N cycle in general.     

Carbon sequestration and soil microbes in purple paddy soil as affected by long-term fertilization

Soil organic carbon (SOC) sequestration impacts on food security and climate change and may be affected by soil microbes in fertilized croplands. A 12-year field experiment under the rice–wheat system was used to evaluate the effect of the long-term fertilization on the SOC accumulation, culturable soil microbes, and their interaction in purple paddy soil. Results showed that varied fertilizations resulted in a significant increase of the SOC content and stock in the plow layer, as well as rise in populations of major soil microbes, including bacteria, actinomycetes, and fungi compared with no fertilization. Soil with combined application of chemical NPK fertilizer and organic amendment (pig manure or rice straw return) on average had the highest organic carbon content and stock, amounts of bacteria, actinomycetes, and fungi, which were 7.8%, 5.8%, 75.8%, 130.5%, and 16.2% higher than the NPK fertilization alone. Fertilization differentially altered populations of the functional anaerobic bacteria in paddy soil. With the combined application of chemical NPK fertilizer and organic amendment, soil displayed higher amounts of anaerobic cellulolytic bacteria, anaerobic fermentative bacteria, hydrogen-producing acetogen, methanogenic bacteria, denitrifying bacteria, and sulphate-reducing bacteria than that with the NPK fertilization alone or no fertilization. Populations of all three major soil microbes showed significantly positive correlations with the SOC content, indicating their interaction was of mutual promotion. Data suggest that the combined application of the NPK fertilizer with organic amendment especially by the rice straw return is recommended to sustain the soil biological fertility and mitigate the emission of the greenhouse gas by the SOC sequestration in purple paddy soil.     

种植蔬菜地与裸地氧化亚氮排放差异比较研究

采用大型原状土柱试验研究了种植蔬菜地与未种植蔬菜裸地土壤氧化亚氮（N2O）排放的差异。试验结果表明,施肥但未种植蔬菜的裸地土壤N2O排放量远大于种植蔬菜地的土壤N2O排放量,裸地土壤N2O平均排放通量为193μg.m-2.h-1,而种植蔬菜后土壤N2O平均排放通量减少至60μg.m-2.h-1;相应地,裸地的N2O排放总量也要远高于种植蔬菜地的N2O排放总量。同时,低施氮量（N1,500 kg.hm-2）下裸地的N2O排放量要比高施氮量（N2,750 kg.hm-2）且种植蔬菜时裸地的N2O排放量大,如2007年10月至2008年9月试验期间,N1处理下裸地总N2O-N排放量为9.54 kg.hm-2,而N2处理（种植蔬菜）下总N2O-N排放量仅为4.21 kg.hm-2。此外,未种植蔬菜时裸地土壤N2O排放系数远大于种植蔬菜时,如N1种植蔬菜时为0.39%,但未种植蔬菜的裸地土壤排放系数为1.76%。研究说明种植作物与否对土壤N2O排放有重要影响,因此在估算农田土壤N2O排放温室气体量时,需考虑裸地的贡献能力。     

牧草植物篱对紫色土坡耕地水土流失及土壤肥力空间分布的影响

植物篱的水土保持效果已得到广泛的认可,并在世界很多地方推广.随着经济植物篱概念的提出,牧草已作为经济植物篱植物得到广泛应用.然而,到日前为止,牧草植物篱对坡耕地土壤肥力的影响规律研究却很少.利用长期定位小区试验,研究了苜蓿(Medicago saliva Linn.)和蓑草(Eulaliopsis lsinata(Retz.)C.E.Hubb.)植物篱对坡耕地土壤肥力的影响规律,旨在弄清牧草植物篱提高土壤肥力的作用与效果,不断完善植物篱技术.研究发现,坡耕地在建立牧草植物篱后,土壤粘粒在篱前富积,篱下加剧侵蚀,粘粒的富积与侵蚀沿等高线成水平带状分布;土壤有机质、N、P等主要营养元素出现与土壤颗粒相同的分布规律;对K来说,其分布不受植物篱的影响.表现出从坡上向坡下逐渐减少的分布特点.从土壤养分的绝对数量来看,P呈高度富积,而有机质和K则足高度耗竭.因此,坡耕地施肥时可以适当减少P的施用量,增加有机物和K的施用量.针对植物篱带对坡耕地肥力影响的特点,即篱前肥力升高,篱下肥力下降,在坡耕地管理上应特别加强篱下土壤带的培肥,以提高坡而整体生产能力.