N_2O emissions from agricultural soils in the North China Plain: the effect of chemical nitrogen fertilizer and organic manure

An enclosed chamber technique was used to measure N 2O emissions from intensively agricultural soils of the North China Plain during the periods of 1995—1996 and 1997—1998, to reflect distinct components of winter wheat and summer maize growing seasons. The results showed that the continuous application of fertilizer in agricultural soils increased N\-2O emissions by a factor of 24.1—28.1, the calculated annual chemical N fertilizer\|transformed N\-2O\|N emissions was 0.67%. Our results indicated that the application of organic manure also had a significant influence on soil N 2O emissions, which combined with the use of chemical N increased about 20% in a year. It was calculated that there were about 0.11% N of organic manure transformed as N 2O N. Annual mean N 2O emission from our study area of fertilized soils was estimated to be 57.1 μgN 2O/(m 2·h). A weak correlation was also found between N 2O emissions and soil available nitrogen content NH + 4.

Effect of Long-Term Fertilization on Organic Nitrogen Forms in a Calcareous Alluvial Soil on the North China Plain

In order to illustrate the change of nitrogen （N） supply capacity after long-term application of manure and chemical fertilizer, as well as to properly manage soil fertility through fertilizer application under the soil-climatic conditions of the North China Plain, organic N forms were quantified in the topsoil with different manure and chemical fertilizer treatments in a 15-year fertilizer experiment in a Chinese calcareous alluvial soil. Soil total N （TN） and various organic N forms were significantly influenced by long-term application of chemical fertilizer and manure. TN, total hydrolysable N, acid-lnsoluble N, amino acid N and ammonium N in the soil increased significantly （P 〈 0.05） with increasing manure and fertilizer N rates, but were not influenced by increasing P rates. Also, application of manure or N fertilizer or P fertilizer did not significantly influence either the quantity of amino sugar N or its proportion of TN. Application of manure significantly increased （P 〈 0.05） hydrolysable unknown N, but adding N or P did not. In addition, application of manure or N fertilizer or P fertilizer did not significantly influence the proportions of different soil organic N forms.

Soil Properties and Yield of Jerusalem Artichoke(Helianthus tuberosus L.)with Seawater Irrigation in North China Plain

Irrigation with various dilutions of seawater can act as an alternate water resource and thus plays an important role in saving freshwater resources as well as promoting agriculture in the coastal semi-arid areas of the North China Plain. Jerusalem artichoke （Helianthus tuberosus L.） grown in a field experiment was irrigated with seawater diluted with freshwater from 2001 to 2003 to determine the feasibility of seawater irrigation in the Laizhou area. For treatments of CK （non-irrigation） along with seawater concentrations of 25%, 50%, and 75%, total dissolved solid （TDS） in the non-irrigated soil significantly increased （P ≤ 0.05） in both 2002 and 2003 and was 1.3 times higher in 2003 than in 2001. In the 25% and 50% seawater concentration treatments, TDS in 2001 was significantly greater （P ≤ 0.05） than CK; however, TDS in these two treatments decreased by 34.9% and 40.1%, respectively, in 2003 compared with 2001. The sodium adsorption ratio （SAR） remained below 10 mmol^1/2 L^-1/2, indicating that alkalization was low with seawater irrigation. In 2001 and 2002, compared to CK and the irrigation treatment with 75% seawater, irrigation with 25% and 50% seawater increased the yields of Jerusalem .artichoke. This meant that Jerusalem artichoke could be safely grown in salt-affected land of Laizhou area with 25% and 50% seawater irrigation.

Influences of drip and flood irrigation on soil carbon dioxide emission and soil carbon sequestration of maize cropland in the North China Plain

The need is pressing to investigate soil CO2 （carbon dioxide） emissions and soil organic carbon dynamics under water-saving irrigation practices in agricultural systems for exploring the potentials of soil carbon sequestration. A field experiment was conducted to compare the influences of drip irrigation （DI） and flood irrigation （FI） on soil organic carbon dynamics and the spatial and temporal variations in CO2 emissions during the summer maize growing season in the North China Plain using the static closed chamber method. The mean CO2 efflux over the growing season was larger under DI than that under FI. The cumulative CO2 emissions at the field scale were 1959.10 and 1759.12 g/m2 under DI and FI, respectively. The cumulative CO2 emission on plant rows （OR） was larger than that between plant rows （BR） under FI, and the cumulative CO2 emission on the irrigation pipes （OP） was larger than that between irrigation pipes （BP） under DI. The cumulative CO2 emissions of OP, BP and bare area （BA） under DI were larger than those of OR, BR and BA under FI, respectively. Additionally, DI promoted root respiration more effectively than FI did. The average proportion of root respiration contributing to the soil CO2 emissions of OP under DI was larger than that of OR under FI. A general conclusion drawn from this study is that soil CO2 emission was significantly influenced by the soil water content, soil temperature and air temperature under both DI and FI. Larger concentrations of dissolved organic carbon （DOC）, microbial biomass carbon （MBC） and total organic carbon （TOC） were observed under FI than those under DI. The observed high concentrations （DOC, MBC, and TOC） under FI might be resulted from the irrigation-associated soil saturation that in turn inhibited microbial activity and lowered decomposition rate of soil organic matter. However, DI increased the soil organic matter quality （the ratio of MBC to TOC） at the depth of 10-20 cm compared with FI. Our results suggest that the transformation from conventional FI to integrated DI can increase the CO2 emissions and DI needs to be combined with other management practices to reduce the CO2 emissions from summer maize fields in the North China Plain.

SOIL SALINITY CONTROI,REGARDING SUBSURFACE WATER REGULATION IN NORTH CHINA PLAIN

The North China Plain (NCP) lying along the eastern coastal area withgeogriaphical coordinates 100°to 120°and 30° to 40°W, is one of the mostimportan agncultural ngons in China. A problem in soil salmization has beenfound in vast areas along the lower reaches of the Yellow hiver and north of it. After30 years of work on saline soil amelioration, 2.0 million ha has been improved,accounting for over 60 percen of the total ongnal saline soil area. Ths achievetnenthas ban obtained in close relation to water conservancy work. The author analyzessalthezation amelioration by using measures concerning subsuffoce water regulation.Ih addition to water conservancy measures, thes paper also descnbes acomprehensive way to ameliorate salthezation in northem NCP. Finally, the authorstresses the necessity of combining all measures together into a whole system forsolving salinization problems in northem NCP.

The Relationship between Spring Soil Moisture and Summer Hot Extremes over North China

The increase in the occurrence of hot extremes is known to have resulted in serious consequences for human society and ecosystems. However, our ability to seasonally predict hot extremes remains poor, largely due to our limited understanding of slowly evolving earth system components such as soil moisture, and their interactions with climate. In this study, we focus on North China, and investigate the relationship of the spring soil moisture condition to summer hot extremes using soil moisture data from the Global Land Data Assimilation System and observational temperature for the period 1981-2008. It is found that local soil moisture condition in spring is closely linked to summer hot days and heat waves over North China, accounting for 19%-34% of the total variances. Spring soil moisture anomalies can persist to the summer season, and subsequently alter latent and sensible heat fluxes, thus having significant effects on summer hot extremes. Our findings indicate that the spring soil moisture condition can be a useful predictor for summer hot days and heat waves over North China.

Spatio-temporal Variation of Soil Respiration and Its Driving Factors in Semi-arid Regions of North China

Soil respiration （SR） is the second-largest flux in ecosystem carbon cycling. Due to the large spatio-temporal variability of environmental factors, SR varied among different vegetation types, thereby impeding accurate estimation of CO2 emissions via SR. However, studies on spatio-temporal variation of SR are still scarce for semi-arid regions of North China. In this study, we conducted 12-month SR measurements in six land-use types, including two secondary forests （Populus tomentosa （PT） and Robinia pseudoacacia （RP））, three artificial plantations （Armeniaca sibirica （AS）, Punica granatum （PG） and Ziziphusjujuba （Z J）） and one natural grassland （GR）, to quantify spatio-temporal variation of SR and distinguish its controlling factors. Results indicated that SR exhibited distinct sea- sonal patterns for the six sites. Soil respiration peaked in August 2012 and bottomed in April 2013. The temporal coefficient of variation （CI0 of SR for the six sites ranged from 76.98% to 94.08%, while the spatial CV of SR ranged from 20.28% to 72.97% across the 12-month measurement. Soil temperature and soil moisture were the major controlling factors of temporal variation of SR in the six sites, while spatial variation in SR was mainly caused by the differences in soil total nitrogen （STN）, soil organic carbon （SOC）, net photosynthesis rate, and fine root biomass. Our results show that the annual average SR and Q10 （temperature sensitivity of soil respira- tion） values tended to decrease from secondary forests and grassland to plantations, indicating that the conversion of natural ecosystems to man-made ecosystems may reduce CO2 emissions and SR temperature sensitivity. Due to the high spatio-temporal variation of SR in our study area, care should be taken when converting secondary forests and grassland to plantations from the point view of accurately quantifying C02 emissions via SR at regional scales.

Liquid-plastic Limit of Surface Sediments in North Slope of South China Sea

1 Introduction China has a vast area of continental shelf and is very rich in marine resources,but because of the complex geological environment and frequent geological disasters,the utilization of marine resources and the construction of marine engineering are limited(Zhu et al.,2016).As the

华北平原冬小麦-夏玉米农田生态系统土壤自养和异养呼吸模型构建

土壤呼吸是陆地生态系统碳循环的重要过程,准确估算土壤呼吸对估算陆地生态系统碳源汇具有重要意义。通过在华北平原典型农田内开展土壤呼吸及其组分的原位观测实验,构建了适用于华北平原冬小麦-夏玉米轮种制农田生态系统的半经验半机理土壤异养呼吸和土壤自养呼吸模型。结果表明,冬小麦-夏玉米农田土壤异养呼吸模型可表达为土壤温度和土壤水分的函数,其中,土壤温度对土壤异养呼吸的影响适合用Arrhenius方程描述,而土壤水分的影响适合用对称的倒抛物线描述。验证表明,该模型的R^(2)和RMSE分别为0.68和0.52μmol m^(-2)s^(-1)。土壤自养呼吸模型包括维持呼吸和生长呼吸两个模块,其中,维持呼吸表达为土壤温度和叶面积指数的函数,其形式分别为Van′t Hoff指数方程和米氏方程;生长呼吸表达为总初级生产力与维持呼吸之差的线性函数。冬小麦季和夏玉米季土壤自养呼吸模型的结构相同,但是两种作物的模型参数差异较大。验证表明,冬小麦季土壤自养呼吸模型的R2和RMSE分别为0.64和0.50μmol m^(-2)s^(-1),夏玉米季土壤自养呼吸模型的R2和RMSE分别为0.67和0.37μmol m^(-2)s^(-1)。相比于不区分土壤异养呼吸和土壤自养呼吸的土壤总呼吸模型,本研究构建的土壤异养呼吸和土壤自养呼吸模型能够更加准确地模拟土壤呼吸的季节变化和年际变化过程,可为华北平原冬小麦-夏玉米轮种制农田生态系统的土壤呼吸估算提供方法依据。

华北平原禹城地区地下水埋深对地下水及土壤水分和盐分分布的试验研究

【目的】研究不同浅层地下水埋深下的土壤水盐分布规律及其对作物产量的影响。【方法】在体积蒸渗仪样地中设置4个地下水埋深处理,分别为G0(无地下水埋深)、G1(地下水埋深40 cm)、G2(地下水埋深70 cm)、G3(地下水埋深110 cm)和G4(地下水埋深150 cm),监测夏玉米在自然蒸发条件下的浅层地下水盐分离子量变化和夏玉米收获后土壤水分和盐分的垂直变化。【结果】(1)地下水埋深越深,表层(0~20 cm)土壤含水率与含盐量越低。与G0处理相比,G1处理和G2处理表层土壤含水率分别显著增加27.54%和26.97%,G3处理增加8.25%,而G4处理仅增加2.18%;G1、G2、G3处理表层土壤含盐量分别增加0.79、0.47、0.43 g/kg,而G4处理则减少了0.01g/kg。G1、G2、G3处理下的盐分主要积累在表层土壤,G4处理主要积累在40~70 cm土层;(2)地下水埋深与表层(0~20 cm)土壤含水率与含盐量呈线性关系,地下水埋深每增加0.1 m,表层土壤含水率降低0.53%,含盐量降低0.065 g/kg。(3)浅层地下水中的主要阳离子为Na^(+)、Mg^(2+),主要阴离子为SO_(4)^(2-)和HCO_(3)^(-),集中降水使浅层地下水中离子由Na-Cl·SO_(4)向Na-HCO_(3)转化;(4)在强烈的地表蒸发下,地下水埋深越浅,地下水中离子浓度上升越快。其中HCO_(3)^(-)浓度在各处理中波动较大,总体呈上升趋势;而NO_(3)^(-)由于施肥的影响,地下水埋深越浅,NO_(3)^(-)在浅层地下水中达到峰值的速度越快,且浓度越高。【结论】增加浅层地下水埋深可有效降低表层土壤水盐量,减小浅层地下水受蒸发、降水的影响。浅层地下水埋深为1.2 m最适宜夏玉米生长,产量最优。研究不同浅层地下水埋深对农田土壤水分和盐分的影响有助于掌握农业生态系统中水盐迁移以及地下水与土壤的相互作用机制,对于防止土壤盐渍化、保障作物产量具有重要意义。

施用粪肥对我国北方农田土壤呼吸温度敏感性的影响

[目的]本研究旨在探明粪肥施用对我国北方农田土壤呼吸温度敏感性Q_(10)的影响及主要驱动因素,为制定合理的农业管理措施、减少农田土壤CO_(2)排放提供科学依据。[方法]本研究在中国知网、万方数据和Web of Science数据库收集国内外关于施用粪肥对土壤呼吸温度敏感性影响的相关文献,用关键词“粪肥”、“土壤呼吸”、“温度敏感性”和“中国北方”进行检索,共提取已公开发表的16篇文献中试验数据104组。采用整合分析(Meta-analysis)探讨不同粪肥施用条件下各因素对土壤呼吸温度敏感性的影响。[结果]粪肥施用可显著提高土壤呼吸温度敏感性,平均提升幅度为8.11%。施肥类型中,猪粪对土壤呼吸温度敏感性的增幅(12.72%)显著高于鸡粪的增幅(5.56%);粪肥施用量≤15000 kg·hm^(-2)对土壤呼吸温度敏感性的增幅最大(11.48%);单施粪肥的增幅(11.96%)显著高于粪肥配施化肥的增幅(5.22%)。土壤有机碳含量≥12 g·kg^(-1)时土壤呼吸温度敏感性的增幅(7.17%)显著高于6~12 g·kg^(-1)水平(2.23%)时的增幅;土壤初始pH≥7的增幅(8.11%)显著高于pH<7的增幅(3.48%)。不同气候条件下,年均温≤5℃时土壤呼吸温度敏感性的增幅为8.49%,年降雨量为400~600 mm时的增幅(8.98%)显著高于≤400 mm(2.71%)和≥600 mm时的增幅(-3.13%)。此外,随机森林结果表明土壤有机碳含量是影响土壤呼吸温度敏感性变化的关键因素,其解释率达42.6%。[结论]综上,在我国北方农田鸡粪配施化肥且粪肥施用量>15000 kg·hm^(-2)对土壤呼吸温度敏感性的增幅最小,可以有效减缓农田土壤的碳排放,以达到应对全球变暖现状的目的。此外,土壤有机碳含量是影响粪肥施用下中国北方农田土壤呼吸温度敏感性变化的主要驱动因素。

环丙沙星在地下水灌区土壤的吸附解吸特征

为了更全面认识环丙沙星(CIP)在不同背景土壤中的迁移特性,在华北平原地下水灌溉农田区选择有机质组成特征和理化性质显著的两处土壤样品,从动力学和热力学两方面研究CIP在土壤中的吸附-解吸机制。结果显示,动力学实验数据更符合准二级动力学方程,等温模式呈非线性特征、Langmuir模型拟合效果最优。吸附动力学常数(K_(2),8 772.64 vs 2 846.37 g/(mg·h))、吸附平衡速率常数(Kl,0.113 vs 0.094 L/mol)及最大吸附量(Q_(m),5 033 vs 3 167 mg/kg)参数均呈现出献县样品大于正定样品,指示献县土壤更快的吸附速率和更大的吸附容量。相应地,解吸实验得到的解吸率(5.98%vs 8.07%)、最大解吸量(6 592 vs 7 564 mg/kg)及由热力学计算所得吸附自由能ΔG(-25.08 vs-23.00 kJ/mol)大小均一致反映出献县土壤相较正定土壤对CIP的吸附性能更强。综合实验研究结果和光谱特征、理化参数特征分析得出,献县土壤的高分子、高芳香性和多官能团的腐殖质成分以及更高黏粒含量是其吸附性能整体表现更强的重要因素,腐殖质分子的疏水作用和静电作用等物理吸附机制可能对献县土壤吸附CIP起到更加积极的作用。

北方土石山区薄土坡耕地石坎反坡阶措施减流减沙效益分析

为解决我国北方土石山区薄土坡耕地水土流失问题,通过布设标准径流小区来研究石坎反坡阶措施的水土保持综合效果。结果表明:石坎反坡阶措施对于坡耕地水土流失调控效果显著,该措施相较于等高耕作措施,坡面径流削减率和泥沙削减率分别达到68.57%和94.29%;石坎反坡阶措施在提高坡面土壤水分含量、提高坡面水分分布均匀度方面能够发挥出良好的作用,该措施相较于等高耕作措施,坡面总体土壤水分含量提高了7.78%;石坎反坡阶措施能够显著提高坡耕地的农作物产量,相较于常规等高耕作措施,玉米产量提高了12.69%。石坎反坡阶的设计及作用效果研究,丰富了我国北方土石山区薄土坡耕地的水土流失治理途径。

改进密闭室抽气法以准确定量旱地土壤氨挥发

密闭室抽气法被认为是定量土壤NH_(3)挥发较为可靠的方法,具有灵敏度高且成本低的优点。然而,大部分研究忽略了密闭室抽气法大气进气口NH_(3)浓度,可能会高估土壤NH_(3)挥发量,目前尚缺乏相关定量研究。本研究以华北冬小麦-夏玉米轮作为对象,对比分析了2019——2021年间冬小麦基肥(2次)、追肥(1次)、夏玉米四叶肥(2次)、夏玉米十叶肥(2次)共7次施肥后,改进密闭室抽气法前后测定农田土壤NH_(3)挥发的结果。改进前为包含大气背景NH_(3)的测定方法,为常规测定方法;改进后为扣除大气背景NH_(3)的测定方法,通过在田间加装3套采集距地面2.5 m高度大气的装置实现。结果表明:改进后的NH_(3)挥发通量(以N计)比改进前低0~0.23 kg·hm^(-2)·d^(-1)(0%~100%),平均值为0.06 kg·hm^(-2)·d^(-1)(33%),且37%的样本存在显著性差异(P<0.05,n=931)。改进后的NH_(3)挥发累积量比改进前低0.53~2.66 kg·hm^(2)(3%~53%),平均值为1.15 kg·hm^(-2)(29%),且47%的样本存在显著性差异(P<0.05,n=49)。改进前后NH_(3)挥发量(包括通量和累积量)存在显著差异的样本占比随着NH_(3)挥发量降低而升高。回归分析表明,改进前的NH_(3)挥发累积排放量可以用算式校正得到真实的NH_(3)累积排放量,校正式为y=0.94x-0.78(R2=0.99,P<0.01,n=49),其中y和x分别为校正后和校正前的NH_(3)挥发累积量,该算式可应用于华北土壤-作物体系NH_(3)挥发累积量的校正。综上,利用抽气法定量农田土壤NH_(3)挥发需要扣除大气背景NH_(3)以得到准确的测定结果,对于未扣除大气背景的旱地NH_(3)挥发累积量,可采用校正算式进行校正。

朔州市华北落叶松防护林生长状况及天然更新情况调查

目的调查朔州市华北落叶松防护林生长状况、土壤肥力,分析华北落叶松的天然更新情况。方法以朔州市华北落叶松防护林为研究地点,所有林分均为天然更新,按照不同林龄,将华北落叶松分为10~20a(Z1)、20~30a(Z2)和30~40a(Z3)3组样地,每组样地(50 m×50 m),采用回归分析等方法,对华北落叶松不同林龄其幼苗更新生长状况、土壤理化性质和林分天然更新情况进行分析。结果:①幼苗生长状况:华北落叶松防护林不同林龄间其幼苗长势良好,苗高、地径等指标以Z2最佳,表现为Z2>Z1>Z3,组间比较有显著差异(P<0.05),其中Z2落叶松株数低于Z1和Z3(P<0.05),且其中Z3>Z1(P<0.05);②土壤肥力:3组pH值比较无差异(P>0.05),Z2土壤有机质、全氮、全磷和速效钾含量明显高于Z1>Z3(P<0.05);③天然更新状况:Z2落叶松幼苗天然更新状况明显优于Z1和Z3,说明林龄、密度和土壤肥力直接影响林下幼苗天然更新情况。结论华北落叶松防护林20~30 a林龄下,幼苗密度良好,土壤肥力较佳,林间天然更新动态良好。

Comparative Characteristic of Aeolian Loessial Soils Samples

Comparative characteristic of aeolian loessial soils samples,whose sections are from North China (Beijing)and pre-Caucasia(Bujennovck).As far as we know,there are many questions can be researched in the area of loess.For the sake of solving engineering and ecogeological problems,we have to begin with knowing loess’ composition,structure, physical,physicochemical,physicomechanical properties and first of all—the property of sedimenttation.

华北地区粮食作物种植结构调整及水土资源利用效应

华北地区粮食生产种植结构调整对水土资源消耗的影响,对农业甚至国民经济的可持续发展有重要意义。利用统计数据,以初期(2001年)种植结构不变为参照情形,在末期(2019年)粮食产量一定的条件下,估算了2001—2019年华北地区粮食种植结构调整的水土资源效应。结果表明:2001—2019年华北地区粮食播种面积增加,玉米是粮食作物播种面积增加的主要因素,2001—2019年华北地区小麦播种面积增加,小麦播种面积占粮食播种面积比重降低幅度较小;2001—2019年华北地区粮食种植结构调整一定程度上缓解了耕地资源有限、水资源短缺、地下水超采压力。提出以下建议:通过加大轮作休耕、旱作雨养面积等政策措施减少高耗水作物种植面积,进一步降低华北地区水土资源消耗压力;进一步提高山东省和河南省因粮食种植结构调整播种面积节约率;进一步提高山东省、河南省、河北省粮食种植结构调整的节水效应。

华北平原不同土地利用方式下土壤饱和导水率特征及其影响因素

为了探究华北平原不同土地利用方式下土壤结构及养分与土壤饱和导水率的关系,研究了6种类型样地(乔木混交林地、乔木纯林地、灌木林地、草地、果园、耕地)的土壤物理结构特征及其与饱和导水率之间的关系。结果表明:不同土地利用方式样地的土壤容重整体表现为耕地>草地>果园>灌木林地>纯林地>混交林地,土壤含水率整体表现为混交林地>纯林地>灌木林地>耕地≈草地>果园,土壤全氮、速效钾及速效磷均整体表现为混交林地>纯林地>灌木林地>草地>果园>耕地,土壤总孔隙度整体表现为混交林地>灌木林地>纯林地>果园>草地>耕地,土壤石砾含量未表现出整体的差异规律,但果园及耕地的土壤石砾含量随着土壤深度的增加而增加。土壤饱和导水率整体表现为混交林地>纯林地>草地>果园≈耕地,不同土地管理下的土壤容重、土壤总孔隙度、土壤含水率、土壤全氮、速效钾、速效磷变化均是影响土壤饱和导水率特征的主要因子,其中土壤容重越小,土壤总孔隙度、土壤含水率、土壤全氮、速效钾、速效磷越大,则土壤饱和导水率越大。混交林及灌木林有利于土壤导水及提水性能的提升;在今后对区域土壤性质及饱和导水率的研究中不能忽略土地利用管理方式及人为干扰的重要影响。

Effects of Poplar Plantations on the Physical and Chemical Properties of Soils:A Case Study in the North China Plain

In recent years, large areas of farmland in the North China Plain have been converted into short-rotation poplar plantations. To analyze the impacts of poplar plantations on soil, 22 soil samples were collected and assayed from the soil profiles of a corn field and a poplar plantation. The results showed that the average soil moisture content of the soil profile in the poplar field was 2.6 percent lower than that of the arable land. The maximum dif- ference in soil moisture content was found in the upper 0-10 cm of topsoil. Soil organic matter and nitrogen, phosphorus and potassium in the cornfield were significantly higher than in the poplar field. Higher nutrient content in the corn field may result from higher fertilizer inputs and the practice of returning straw to the cropped field. The analysis also showed no significant increase in soil organic matter content in deeper soil layers of the poplar field, which means that the conditions are not favorable for the formation of soil organic matter, or that soil organic matter needs a longer time to develop. Elements such as magnesium, iron, manganese and copper in both the corn field and the poplar field had a tendency to accumulate with increasing soil depth. Magnesium, iron, manganese and copper in the 0-80 cm soil layer of the poplar field were higher than those of the cornfield, but the situation was reversed at depths greater than 80 cm. It is concluded that poplar trees consume a large amount of soil moisture and soil nutrients. Local governments should prevent the development of new plantations of fast-growing trees in farmland and help farmers to recover their farmland from forestry plantations.

北方地区土壤速效养分及容重对秸秆还田的响应

本研究旨在探明中国北方地区土壤速效养分及容重对秸秆还田的响应,选择秸秆还田为主要研究目标,通过设置“秸秆还田”、“理化性质”、“华北”、“东北”、“西北”等关键词在中国知网、万方等多个数据库中,筛选出60篇关于秸秆还田对作物产量和土壤改良影响效应和影响因素的文献。采用Meta分析法定量研究土壤速效养分和容重对秸秆还田的响应。结果表明:秸秆还田能够显著(P<0.05)提升土壤有机碳、碱解氮和速效钾的含量,一定程度上降低土壤容重。华北地区秸秆还田对土壤速效养分的提升效果显著优于东北和西北地区,而对西北地区容重降低效果低于华北和东北地区;中高量秸秆还田(5000~10000 kg/hm^(2)和10000~15000 kg/hm^(2))能够显著提升土壤有机碳、碱解氮和速效钾的含量,低秸秆还田量(≤5000 kg/hm^(2))对土壤容重并无显著影响,而超高秸秆还田量(>15000 kg/hm^(2))则显著(P<0.05)降低了土壤容重;免耕相比旋耕、深耕、浅耕可以显著(P<0.05)提升土壤有机碳、碱解氮和速效钾的含量,深耕可显著(P<0.05)降低土壤容重;小麦和玉米秸秆均对土壤容重和速效养分的提升有显著效果,但两种作物秸秆间并无显著差异。北方地区推荐中高量秸秆还田配合免耕措施,不仅能够显著增加土壤养分含量,而且可改善土壤理化性质,从而达到培肥地力的效果。