鄂尔多斯高原农田土壤类型与养分组成对微量元素的影响——以鄂托克旗为例

以鄂尔多斯高原的鄂托克旗为研究区域,结合统计分析探索鄂托克旗土壤微量元素含量特征,以及土壤类型和土壤养分对土壤微量元素(铜、铁、锰、锌、硼)的影响,以期为当地肥料使用提供参考。研究结果表明:①鄂尔多斯高原农田土壤铁、锰、铜、锌、硼有效态含量中等,铁和锰含量变异相对较小,铜、锌和硼含量变异相对较大;②不同土壤类型对土壤中的微量元素含量具有显著影响;③铁、锰和硼有效态含量与pH值呈极显著负相关,有效铜含量与pH值呈极显著正相关,pH值过高会影响土壤中铁、锰、铜和硼的有效态含量。     

广元植烟土壤有效态微量元素的空间变异特征及影响因素

为揭示广元植烟区土壤有效态微量元素含量空间变异特征及影响因素,采用地统计学、相关分析及回归分析等研究方法,结合地理信息系统(GIS)技术对研究区土壤有效铁、锰、铜、锌钼及硼等6种土壤有效态微量元素进行分析。结果表明,研究区土壤有效铁、锰及铜含量丰富,总体处于中等以上水平;有效钼含量适中;有效锌和硼缺乏,总体处于缺乏或极度缺乏水平。半方差分析表明,6种土壤有效态微量元素块金系数均在29.72%~67.59%之间,具有中等强度的空间自相关性,其空间变异受结构性因素和随机性因素共同影响。空间分布上,土壤有效铁、锰、铜及钼含量表现出北高南低的空间分布趋势,土壤有效锌和硼含量呈现出西高东低的空间分布格局。影响因素分析表明,6种土壤有效态微量元素与土壤有机质呈正相关,与p H值呈负相关,相关性总体高于地形因子。土壤有机质对有效铁、铜、锌及硼有极显著影响,其空间变异性为5.5%~27.2%。除有效锌外,土壤p H值对其余5种土壤有效态微量元素含量空间变异均有极显著影响,其空间变异性为5.0%~30.4%。土类对土壤有效铁、锰及铜有极显著影响,其空间变异性8.4%~12.3%。熟制和种植制度对6种土壤有效态微量元素含量空间变异的影响较弱,进一步说明研究区土壤有效态微量元素含量空间变异受结构性因素和随机性因素共同影响,但结构性因素的作用强于随机性因素。本研究结果为广元植烟区土壤微肥施肥管理及优质烤烟栽培提供了可靠的参考依据。     

豫中植烟土壤有效态微量元素与pH和有机质的关系

为探明豫中植烟土壤p H和有机质对微量元素有效态含量的影响，在豫中许昌市的建安、禹州、襄城和漯河市的城区、临颍和舞阳6个植烟县(区)采集了191个典型烟田耕层(0～20 cm)土样，测定了微量元素(有效铜、铁、锰、锌、钼)含量、p H和有机质含量，采用Pearson相关分析法与曲线回归方法分析了有效态微量元素含量与pH、有机质之间的关系。结果表明，有效铜、铁、锰、锌和钼的平均含量分别为1.20、49.24、84.80、1.71和0.02mg/kg，有效锰总体上充足，有效钼整体极为缺乏，个别样点有效铜、铁和锌缺乏；p H平均为7.90，总体上偏高；有机质平均为17.78g/kg，总体上适宜；微量元素有效态与pH、有机质之间均存在二次函数关系，随p H升高，有效铜呈增加趋势，有效铁和锌呈先升后降趋势，有效锰和钼呈先降后升趋势；随有机质升高，有效铜、锰、锌和钼呈增加趋势，有效铁呈先升后降的趋势。     

不同施肥方式对典型壤质潮土中微量元素积累及其有效性的影响

研究了1989-2009年间长期不同施肥方式对华北地区典型壤质潮土微量元素全量及有效性的影响。田间试验施肥处理包括：有机肥（OM）、1/2OM 1/2化肥氮磷钾（NPK）、NPK、NP、PK、NK和不施肥（CK）,每个处理4个重复。结果显示,经过长期不同施肥,铁（Fe）、锰（Mn）、铜（Cu）、锌（Zn）等微量元素在表层土壤（0～20cm）中均有一定积累,与其在不同土层中的迁移有关。形态分级提取结果表明,土壤中有效态铁（DTPA-Fe）、铜（DTPA-Cu）、锌（DTPA-Zn）含量高于其在碱性土壤中的最低标准,而有效态锰（DTPA-Mn）的含量则相对较低;残渣态(Residual-faction)是微量元素在土壤中的主要形态,分别占其全量的>90%（Fe）、>54%（Mn）、>70%（Cu）、>70%（Zn）。有机质在土壤中的积累通过多种机制提高了有效态、弱酸溶解态（Acid-soluble-fraction）及可氧化态（Oxidizable-faction）微量元素的含量,有效缓解了土壤有效态锰含量的不足,抑制了磷与锌的沉淀反应,是影响微量元素形态转化的主要原因。钾肥的施用同样提高了有效态及弱酸溶解态微量元素的含量,但降低了铁、锰在表层土壤中的全量;而磷肥施用则通过沉淀反应降低了有效态及弱酸溶解态微量元素的含量,提高了铜、锌在表层土壤中的全量。     

土地整理对土壤有效态微量元素的影响

以重庆丰都县三坝乡土地整理项目为研究对象,研究土地整理前后的土壤有效态微量元素铁、锰、铜、锌、硼含量及分布特征,并进一步探讨其变化的原因。结果表明:(1)土地整理后土壤有效态铁、锰、铜、锌、硼的含量均下降,其中有效铁含量下降最明显,较整理前减少72.7%;土地整理改变了土壤有效态微量元素(除有效硼外)的剖面分布规律,使离散程度降低,使各土层中微量元素的含量趋于均匀。(2)土壤有机质、pH和速效养分能影响微量元素的分布。土地整理后土壤有机质含量的下降能显著降低表层(0-20cm)土壤中有效态微量元素含量,其中土壤有效铜含量受其影响最为明显,相关系数r为0.773;随着土壤pH的增加,表层(0-20cm)和亚表层(20-40cm)中有效态微量元素含量降低,其中有效铁含量受pH影响较为显著;土壤中有效磷含量的下降是造成表层和亚表层土壤有效态微量元素含量下降的另一原因,速效钾对底层(40-60cm)土壤中有效态铁和有效态锌含量有一定的影响,相关系数分别为0.494和0.510,土壤中碱解氮含量的变化对有效态微量元素含量影响不大。     

DCD 在不同质地土壤上的硝化抑制效果和剂量效应研究

通过硝化抑制剂抑制土壤硝化作用是实现作物铵硝混合营养和提高氮肥利用率的重要途径之一。本试验采用室内模拟的方法, 在人工气候室(25 ℃)黑暗培养条件下, 应用新疆石灰性土壤研究了不同剂量的双氰胺(dicyandiamide, DCD)在砂土、壤土、黏土3 种不同质地土壤中对土壤硝态氮、铵态氮转化的影响及DCD 的剂量效应和硝化抑制效果。处理30 d 内, 各剂量DCD 处理对砂土的硝化抑制率为96.5%~99.4%(平均值为98.3%), 在黏土上为66.9%~85.6%(平均值为77.6%), 在壤土上为49.3%~79.4%(平均值为67.7%), 总体硝化抑制率表现为砂土>黏土>壤土。在砂土上DCD 的剂量效应不明显, DCD 用量从纯氮的1.0%增加到7.0%时, 土壤中硝态氮含量仅增加1.9~10.7 mg·kg^-1(培养30 d 时); 而在壤土和黏土中, 土壤硝态氮含量随DCD 浓度的增加而显著下降, 存在明显剂量效应。这说明施用DCD 可显著抑制新疆石灰性土壤的硝化作用过程, 在砂土、壤土、黏土中DCD 的最佳浓度分别为纯氮用量的6.0%、7.0%和7.0%, 并在培养30 d 内发挥显著作用。     

不同砂土和黏土比例对豫中烤烟质量特色的影响

采用池栽方法,在河南宝丰研究了不同砂土、黏土比例对烤烟质量特色的影响。结果表明:烟草各部位干物质的积累量在不同质地土壤上表现为砂质壤土(中质地)黏壤土黏土砂质壤土(粗质地),2/3砂土+1/3黏土处理的烟草各部位的干物质积累量都最大,单叶重则表现为:2/3砂土+1/3黏土1/3砂土+2/3黏土100%黏土100%砂土;烟叶的外观质量、烟叶中化学成分的协调性、香气成分及感官品质及风格特征均以2/3砂土+1/3黏土处理最优。综合来说,2/3砂土+1/3黏土,土壤砂粒比例分别达到50%,粉粒比例达到30%,黏粒比例低于20%最适宜烤烟质量及品质特征的形成。     

河南省砂土微量元素状况研究

对河南省几种主要砂土的微量元素状况进行研究的结果表明：各种砂土的有效铁和有效铜含量丰富，供应能力较好；土壤有效锌、钼、硼、锰含量均低于缺素临界值。砂土微量元素和土壤阳离子代换量、有机质含量呈线性正相关关系，与土壤砂粒含量呈线性负相关，母质不同，砂土微量元素含量差异很大。生产实际中必须重视砂土微量元素的施用。     

太原市土壤中微量元素状况

从１９８０至１９８９年，我们对太原市不同成土母质，不同类型土壤微量元素的含量进行了分析研究。结果表明，花岗岩母质是有效态微量元素含量较高的母质，砂页岩中有效铜、铁含量最高，黄土母质的微量元素含量均低；有效锌、硼（包括盐化潮土）、锰、铜、铁含量在淋溶褐土和棕壤等土壤中较高，而在褐土性土、石灰性褐土、粗骨土、潮土、盐化潮土等土壤含量较低；在太原市土壤中，有效态微量元素含量一般偏低。     

氮肥和土壤质地对滴灌棉花根系分布及产量的影响

通过大田二因素随机区组试验,研究了滴灌条件下不同质地棉田土壤棉花根长密度和根表面积的垂直分布特征及其对产量的影响。结果表明:(1)施肥、灌水都可以显著降低棉花根长密度和根表面积,其关系表现为显著负相关;(2)花期之前棉花在0~20 cm土层根长密度表现为砂土黏土壤土,花期之后表现为砂土壤土黏土;在20~40 cm土层表现为壤土黏土砂土,且深层土壤砂土中棉花根长密度下降势显著高于壤土、黏土;在不同质地土壤中,粗根表面积均表现为N2(施氮量360 kg/hm~2)N3(施氮量480 kg/hm~2)N1(施氮量240 kg/hm~2)CK(不施氮处理);(3)根系分布特征参数与籽棉产量相关性分析结果显示,根长密度、根表面积对籽棉产量的形成均有显著影响,棉花籽棉产量的有效提高手段之一是在某些特定生育期适度地降低根系特征参数。     

土壤紧实度对伴矿景天生长及镉锌吸收性的影响研究

采集黏土、壤黏土和砂质壤土,分别设置无压实、低紧实度及高紧实度3种处理,通过盆栽试验研究了土壤紧实度对Cd、Zn超积累植物伴矿景天生长和Cd、Zn吸收性的影响。结果表明,与无压实处理比较,砂质壤土、壤黏土和黏土中伴矿景天地上部生物量在低紧实度下显著下降66.8%~83.5%、59.9%~60.4%和57.9%~71.4%;高紧实度处理却显著提高了伴矿景天的根系活力(142%~241%)。高紧实度处理显著降低了壤黏土上伴矿景天地上部Cd和Zn含量,但低紧实度对砂质壤土和黏土上伴矿景天地上部Cd和Zn含量无显著影响。与无压实处理比较,低紧实度显著降低了砂质壤土、壤黏土和黏土上伴矿景天的Cd吸取量,分别下降50.4%~73.8%、61.4%~74.9%和43.4%~63.3%,Zn吸取量下降48.7%~79.5%、73.6%~79.0%和46.1%~63.5%;土壤紧实度对壤黏土上伴矿景天的镉锌吸取效率影响最明显。     

不同质地小麦根际土壤有机碳、氮含量及特性研究

测定了两种不同质地土壤小麦根际土及非根际土中不同形态有机碳、氮的含量及特性。结果表明,粘壤土及砂质壤土两种不同质地土壤小麦根际土中有机碳、可溶性有机碳(WEOC),土壤全氮、可溶性有机氮(WEON)、游离氨基酸及硝态氮和铵态氮均显著高于非根际土;根际土及非根际土中WEON的含量均高于硝态氮及铵态氮含量,其在根-土界面氮素转化中的作用值得关注。不同质地土壤相比,粘壤土中各指标的含量均显著高于砂质壤土。根际土有机碳矿化累积量及矿化率均高于非根际土;培养期间粘壤土释放的CO2量明显低于沙质壤土,这可能与粘壤土粘粒含量高,对土壤有机碳的保护作用有关。     

土壤质地对柱花草生长发育、生物量及土壤肥力变化的影响

采用大田试验的方法,在云南省元谋县小雷宰流域内壤土、砂壤土和重壤土3种质地土壤上,以热研5号柱花草为材料,研究土壤质地对柱花草生长发育、生物量及土壤有机质、有机碳、全氮和全磷的影响。试验结果表明:3种土壤质地上种植柱花草,柱花草地上部和地下部生长量和生物量表现幼苗期增加缓慢,而分枝期后增加快的趋势。壤土耕性好,兼有砂土和重壤土的优点,有利柱花草地上部分的生长发育,柱花草地上部生长量、生物量及改善土壤肥力方面显著高于重壤土。砂壤土有利于柱花草根系向深层土壤生长,柱花草地下部生长量、生物量及根瘤显著高于种植在重壤土。在3种土壤质地种植柱花草后,土壤有机质、有机碳、全氮和全磷均有上升趋势。综合而言,通气性和保肥保水能力居中的壤土更适合柱花草的生长发育及干物质的积累。     

互花米草入侵对滨海湿地不同质地土壤碳氮磷及其生态化学计量比的影响

为了阐明外来物种入侵对滨海湿地不同质地土壤碳(C)、氮(N)、磷(P)及其生态化学计量比的影响，对福建省滨海地区东湖湿地两种质地土壤的土著种与入侵种植被下土壤C、N、P含量及其生态化学计量特征与影响因素进行了测定与分析。研究结果表明：相同植被下，壤质土的C、N、P及其计量比均高于砂质土。互花米草入侵增加了两种质地土壤的C、N含量及碳磷比(C/P)、氮磷比(N/P)，降低了土壤有效磷(AP)、P含量与碳氮比(C/N)，其中砂质土的土壤N含量显著增加了近1倍(P<0.05),AP含量下降近70%，壤质土的C/P增加了近2倍(P<0.05)。不同质地土壤中铵态氮(NH₄⁺-N)和硝态氮(NO₃^–-N)含量对互花米草入侵的响应不同，在壤质土中，互花米草入侵后降低了50%的NH₄⁺-N含量，增加了近3倍的NO₃^–-N含量(P<0.05)；而在砂质土中，互花米草入侵后土壤NH₄     

不同土壤质地和含水率对炭基肥料氮素矿化的影响

为了探究土壤特性对炭基肥料氮素矿化的影响,采用室内培养和大田小区试验,分析了炭基肥在不同土壤质地(砂质壤土、粉砂质壤土、黏土)及含水率(80%、60%、40%田间最大持水量)条件下,氮素矿化动态变化特征。结果表明:在室内培养条件下,对于不同土壤质地,炭基肥在砂质壤土条件下矿化势最高,其次为黏土,最低的为粉砂质壤土;对于不同田间持水量,在粉砂质壤土条件下,炭基肥矿化势最高的为80%田间最大持水量(80%SMC),其次为60%SMC,最低的是40%SMC;在砂质壤土和黏土条件下,炭基肥的矿化势均表现为60%SMC>80%SMC>40%SMC。培养状态下粉砂质壤土、砂质壤土、黏土条件下最大氮素有效性分别是34.12%、56.31%、41.14%,而在大田条件下,炭基肥单季氮素最大矿化率在粉砂质壤土、砂质壤土、黏土3种土壤质地下分别是50.61%、32.27%、34.29%。     

肥液浓度对不同形态氮素在土壤中运移转化特性的影响

为揭示肥液(尿素)浓度影响下土壤湿润体中不同形态氮素的运移转化规律,选取黏壤土和砂壤土作为肥液入渗试验供试土壤,量化分析肥液浓度对土壤累积入渗量和不同形态氮素在分布和再分布过程中运移转化特性的影响。结果表明:相同入渗时间内土壤累积入渗量随肥液浓度的增大而增加,Kostiakov公式的入渗系数与肥液浓度呈现线性关系,建立并验证了考虑肥液浓度影响的土壤累积入渗量估算公式,模拟值与实测值具有较高的一致性,两者间的相对误差绝对值均值均8.0%;入渗结束时,土壤湿润体相同位置处的尿素态氮、铵态氮(NH_4~+-N)和硝态氮(NO_3~--N)含量均随肥液浓度的增大而增加;NH_4~+-N主要分布在土壤湿润体深度20 cm以上,尿素态氮和NO_3~--N含量随着湿润体深度的增大呈现下降趋势;再分布过程中,土壤湿润体中尿素态氮含量随再分布时间的增加整体呈现减小趋势,且黏壤土和砂壤土湿润体中的尿素态氮分别在再分布5,3天时基本水解完成;NH_4~+-N含量呈现先增加后减小的趋势,黏壤土湿润体中的峰值约出现在再分布3～5天,而砂壤土约在再分布3天;黏壤土湿润体中NO_3~--N含量呈现先增加后减小的趋势,其峰值约在5～10天,而砂壤土中NO_3~--N含量在再分布10天时,始终保持在较高水平。研究结果为农田灌溉施肥系统的设计和管理提供理论基础和技术支撑。     

Enzyme activities and microbial community structure in semiarid agricultural soils

This study investigated the effect of management on -glucosidase, -glucosaminidase, alkaline phosphatase, and arylsulfatase activities and the microbial community structure in semiarid soils from West Texas, USA. Surface samples (0–5 cm) were taken from a fine sandy loam, sandy clay loam, and loam that were under continuous cotton ( Gossypium hirsutum L.) or in cotton rotated with peanut ( Arachis hypogaea L.), sorghum ( Sorghum bicolor L.), rye ( Secale cereale) or wheat ( Triticum aestivum L.), and had different water management (irrigated or dryland), and tillage (conservation or conventional). The enzyme activities were higher in the loam and sandy clay loam than in the fine sandy loam. Soil pH was not affected by management, but the soil organic C and total N contents were generally affected by the different crop rotations and tillage practices studied. The trends of the enzyme activities as affected by management depended on the soil, but in general crop rotations and conservation tillage increased the enzyme activities in comparison to continuous cotton and conventional tillage. The soil enzyme activities were significantly correlated with the soil organic C ( r -values up to 0.90, P< 0.001), and were correlated among each other ( r -values up to 0.90, P <0.001). There were differences in the fatty acid methyl ester profiles between the fine sandy loam and the sandy clay loam and loam, and they reflected the differences in the enzyme activities found among the soils. For example, a 15:0 ranged from 1.61±0.25% in cotton-peanut/irrigated/no-till in the fine sandy loam to 3.86±0.48% in cotton-sorghum/dryland/conservation tillage in the sandy clay loam. There were no differences due to management within the same soil.Trade names and company names are included for the benefit of the reader and do not infer any endorsement or preferential treatment of the product by USDA-ARS     

Evaluation of pedotransfer functions for estimating the soil water retention points

Direct measurement of soil moisture has been often expensive and time-consuming. The aim of this study was determining the best method to estimate the soil moisture using the pedotransfer functions in the soil par2 model. Soil samples selected from the database UNSODA in three textures include sandy loam, silty loam and clay. In clay soil, the Campbell model indicated better results at field capacity (FC) and wilting point (WP) with RMSE = (0.06, 0.09) and d = (0.65, 0.55) respectively. In silty loam soil, the Epic model had accurate estimation with MBE = 0.00 at FC and Campbell model had the acceptable result of WP with RMSE = 0.03 and d = 0.77. In sandy loam, Hutson and Campbell models had a better result to estimation the FC and WP than others. Also Hutson model had an acceptable result to estimation the TAW (Total Available Water) with RMSE = (0.03, 0.04, 0.04) and MBE = (0.02, 0.01, 0.01) for clay, sandy loam and silty loam, respectively. These models demonstrate the moisture points had the internal linkage with the soil textures. Results indicated that the PTFs models simulate the agreement results with the experimental observations.     

Effect of Induced Soil Compaction on Changes in Soil Properties and Wheat Productivity under Sandy Loam and Sandy Clay Loam Soils: A Greenhouse Experiment

The continuous use of heavy machinery and vehicular traffic on agricultural land led to an increase in soil compaction, which reduces crop yield and deteriorates the physical conditions of the soil. A pot experiment was conducted under greenhouse conditions to study the effects of induced soil compaction on growth and yield of two wheat (Triticum aestivum) varieties grown under two different soil textures, sandy loam and sandy clay loam. Three compaction levels [C₀, C₁, and C₂ (0, 10 and 20 beatings)], two textural classes (sandy loam and sandy clay loam), and two genotypes of wheat were selected for the experiment. Results indicated that induced soil compaction adversely affected the bulk density (BD) and total porosity of soil in both sandy loam and sandy clay loam soils. Compaction progressively increased soil BD from 1.19 Mg m^?3 in the control to 1.27 Mg m^?3 in C₁ and 1.40 Mg m^?3 in C₂ in sandy loam soil while the corresponding increase in BD in sandy clay loam was 1.56 Mg m^?3 in C₁ and 1.73 Mg m^?3 in C₂ compared to 1.24 Mg m^?3 in the control. On the other hand, compaction tended to decrease total porosity of soil. In case of sandy loam, porosity declined by 5% and 17% in C₁ and C₂, respectively, and declined in sandy clay loam by 29% and 54%, respectively. Averaged over genotypes and textures, shoot length decreased by 15% and 26% at C₁ and C₂, respectively, and straw yield decreased by 21% and 61%, respectively. The compaction levels C₁ and C₂ significantly decreased grain yield by 12% and 41%, respectively, over the control. The deleterious effect of compaction was more pronounced on root elongation and root mass, and compaction levels C₁ and C₂ decreased root length by 47% and 95% and root mass by 41% and 114%, respectively, over the control. Response of soil texture to compaction was significant for almost all the parameters, and the detrimental effects of soil compaction were greater in sandy clay loam compared to sandy loam soil. The results from the experiment revealed that soil compaction adversely affected soil physical conditions, thereby restricting the root growth, which in turn may affect the whole plant growth and grain yield. Therefore, appropriate measures to avoid damaging effects of compaction on soil physical conditions should be practiced. These measures may include soil management by periodic chiseling, controlled traffic, conservation tillage, addition of organic manures, and incorporating crops with deep tap root systems in a rotation cycle.     

Guidelines for safe trafficking and cultivation, and resistance–density–moisture relations of three disturbed soils from Alberta

The Atterberg limits and the Proctor compaction test are used by engineers for classifying soils and for predicting stability of building foundations. Field capacity and wilting point (agronomic limits) are used to indicate available water for plant uptake. Few studies have related the engineering criteria to the agronomic ones with regard to compaction hazard for soils. This study investigated the relationships between Atterberg limits, agronomic limits and the critical moisture content (moisture content at Proctor maximum density) for three disturbed soils (sandy loam and clay loam soils from a reclaimed Highvale mine site, and a silt loam soil from a grazing site at Lacombe) of different textures. Relationships between bulk density, moisture content and penetration resistance for these soils were also investigated. For the sandy loam and loam soils, the field capacity was close to the critical moisture content but lower than the plastic limit. Therefore, cultivation of these two soils at moisture contents close to field capacity should be avoided since maximum densification occurs at these moisture contents. Overall, the critical moisture content or field capacity would be a better guide for trafficking of sandy loam and loam textured soils than the Atterberg limits. For the clay loam, field capacity was within the plastic range. Thus trafficking this soil at field capacity would cause severe compaction. In conclusion, either field capacity or plastic limit, whichever is less, can be used as a guide to avoid trafficking at this moisture content and beyond. For the sandy loam and loam soils penetration resistance significantly increased only with increased bulk density (P≤0.05). For the clay loam soil, penetration resistance was positively related to bulk density and negatively related to moisture content.