黄淮海旱作区土壤压实度空间分布特征及其影响因素

为探究旱作区农田不同层次土壤压实度特征,基于2017年采集的255个土壤样品,运用Mann-Kendall突变检验法、地统计学和冗余分析等方法,探究黄淮海旱作区耕作层和压实层空间分布特征,分析不同层次的土壤压实度的空间变异特性及影响因素,并提出了最佳土壤压实度范围。研究结果表明:旱作区耕作层和压实层厚度均呈现由北向南递增的趋势,耕作层最大厚度可达22.50 cm,最低仅有10.21 cm;压实层厚度最大可达17.50 cm,最小值也达到7.50 cm。从不同层次来看,耕作层和压实层的压实度具有空间分布一致性,耕作层压实度高值区主要分布在河南省东部、安徽北部及河北北部地区,最大值可达87.68%以上,低值区则主要集中在山东西北部以及河北南部地区。和压实层压实度相比,耕作层压实度是影响粮食产量的主要因素,且在70%～80%时获得较高产量。分析表明,土壤压实度受到年降水量、平均气温、土壤自然属性等环境因子和机械耕作等人为因素综合作用的影响。研究结果可为黄淮海农田土壤压实情况的改善及管理措施的科学制定提供理论支撑。     

马铃薯枯萎病和干腐病药剂防治筛选试验报告

马铃薯产业是宁夏“1+4”特色优势产业,是西吉县所有农作物中种植面积最大、涉及农户最多、比较效益最高的农民脱贫致富的主导产业。近年来西吉县马铃薯产业由商品薯种植大县向种薯繁育大县的转变,推动了农业增效,农民增收的快速发展。但各类土传性病害的发生影响了马铃薯产业的发展,同时磋商了农民种植的积极性。为了测定筛选出对马铃薯枯萎病和干腐病防治效果好、成本较低药剂,为大田防治提供科学依据。     

吸附到白浆土中铝的解吸行为研究

为探讨发生铝污染的白浆土中金属铝的解吸特性,采用平衡振荡法,研究铝在白浆土中的解吸行为及不同因素的影响。结果表明:在720min后,白浆土中的铝解吸基本达到平衡;25℃下,土壤有机质含量为42.2g/kg,铝在白浆土中的解吸量仅为吸附量的1.5%;用Langmuir方程可很好地拟合白浆土中铝解吸等温曲线(r=0.985 9**),说明表面均匀单层解吸占主导;热力学参数ΔG0,ΔH0,ΔS0,表明铝的解吸是自发、吸热和熵增加的过程。土壤有机质由42.2g/kg降至27.8g/kg时,白浆土中铝的最大解吸量由25.87mg/kg升至66.11mg/kg,且导致解吸滞后现象的加剧。pH降至3时,铝的解吸量升至226.4mg/kg,是pH在5~7时的8倍以上。随着解吸液中NaCl和Na_2SO_4浓度的增加,铝的解吸量增加。总之,吸附到白浆土中的铝解吸能力较弱,但pH和有机质含量降低,无机盐含量升高,铝的解吸量大幅增加,污染风险急剧上升。     

作物模型中单叶最大光合作用速率的温度响应修订

作物的光合作用对温度变化敏感,其温度依存性随品种、生长环境的变化而改变。基于光效率模型的作物生长模型,在应用中很少对光合作用的温度影响参数值进行订正,且在全生育期使用相同的参数值,难免会增加干物质模拟的误差。为此,本文以ORYZA2000模型为例,提出了一种修订光合作用温度影响参数值的方法。为确定方法的有效性,结合2012年和2013年水稻品种两优培九的温度梯度控制实验,首先利用抽穗开花期光合作用观测曲线提取了不同温度水平的光合作用参数值,然后结合Arrhenius方程和Peaked方程建立了温度敏感性参数的温度影响方程。将这些方程代入机理性光合作用模型,模拟了单叶最大光合作用速率与温度的曲线关系。最后,以归一化后的曲线关系修订作物模型参数值,并利用两年地上部分生物量(WAGT)观测值对其验证。结果显示,两优培九单叶最大总光合作用速率随温度的变化关系不同于ORYZA2000的默认设置,修订后的最适温度为38~40°C,高于默认值。在10~20°C的低温段,修订后的温度影响系数低于默认值。从WAGT模拟值的相对误差看,修订后较修订前平均降低约3.3%。本研究为改进干物质模拟精度和分析不同品种光合作用的温度依存性提供了重要参考。     

狭域特有种元江蚬木群落特征及种群结构分析

[目的]通过对元江蚬木群落特征及种群结构的分析,为狭域特有种的生物多样性保育提供理论基础。[方法]采取典型选样法在元江县干热河谷区域元江蚬木集中分布地段设置了5个固定样地和4条样线,调查元江蚬木的种群数量及伴生树种的名称、数量/盖度、胸径、生境特征以及人为干扰状况,根据重要值、生活型及大小级结构等方法分析元江蚬木群落特征及种群结构。[结果]元江蚬木集中分布在元江县的普漂、元洼路、白沟深、鲁业冲以及施坻冲等区域,呈零星或小片断状分布;元江蚬木所处群落的植被类型为季雨林-落叶季雨林,样地中记录到维管植物共计83种,隶属39科69属,其中,落叶树种比例高达90.9%,群落内高位芽植物比例最高,达60.24%,其次是地上芽植物,比例19.28%。调查发现元江蚬木共计412株,种群结构整体呈稳定型,其中,Ⅵ级木(20 cm≤DBH)数量最少,比例9.47%,其次是Ⅴ级(15≤DBH20 cm),比例10.92%,其它大小级个体数量无显著差异;由于人为干扰等原因,衰退型、增长型与稳定型存在于不同的样地或样线。[结论]元江蚬木所处群落的植被类型为季雨林-落叶季雨林;种群结构整体呈稳定型,但增长型、稳定型和衰退型结构在不同地点并存;实生苗和萌枝是元江蚬木种群更新的主要方式,元江蚬木的幼苗和幼树在不同分布地点数量差异很大,生境干旱和人为干扰是影响种群更新的主要原因。     

Soil Nutrients Status after Fifty Years of Tillage and Nitrogen Fertilization

Long-term studies are valuable in assessing the impact of crop management practices on soil sustainability and function. This study used two calculation scenarios, fixed depth and Equivalent Soil Mass (ESM) to assess (i) soil nutrient status and (ii) soil organic carbon (SOC) after 50 years of nitrogen (N) fertilizer application rates (0, 22, 45, and 67 kg N ha^?1) and tillage [clean tillage (CT), reduced tillage (RT), and no-tillage (NT)] in a dryland winter wheat-sorghum-fallow cropping system. The soil organic matter (SOM) content increased by 33% with NT and RT compared with CT. The SOC at 0–30 cm was 39% greater than 30–60 cm depth with both fixed depth and ESM calculations. Soil nutrient specifically soil calcium (Ca), magnesium (Mg), and phosphorus (P) associated with N rates were no different than the control. Crop nutrient removal may eventually reduce soil nutrient contents with only N application. Nutrient addition specifically P should be considered in the future.     

自适应低振动步行轮仿生设计与性能分析

为提高具有高通过性的步行轮平顺性,基于鸵鸟足运动姿态与跖趾关节储能减振机理,运用工程仿生学原理与技术,设计了一种仿生自适应低振动步行轮。有限元数值模拟结果表明,轮上载荷30 N,角速度10(°)/s情况下,相比于传统步行轮,仿生步行轮轮心波动范围在软路面和硬路面分别降低了85.71%和93.33%。采用轻载荷月壤/车轮土槽测试系统验证了仿生步行轮的减振性能。当滑转率小于40%时,仿生步行轮的挂钩牵引力均大于传统步行轮;当滑转率大于40%,且仅在角速度为20(°)/s时,仿生步行轮的挂钩牵引力才小于传统步行轮,表明仿生步行轮在松软地面具有较好的牵引通过性。同时,相比于传统步行轮,当角速度为30(°)/s时,仿生步行轮在软路面和硬路面的加速度分别减少了6.3%和15.8%,振幅分别减小了14.6%和9.6%。在保证松软地面优越牵引通过性能前提下,仿生步行轮比传统步行轮的轮心波动更小,振动明显降低,有效解决了步行轮多边形效应引起的振动问题。     

Nutrient Accumulation in Faba Bean Varieties

Increasing the amount of nutrients in plant-based foods will help to improve the nutritional status of people in the World. Faba bean (Vicia faba L.) as a staple food in developing countries has the potential to provide many nutrients in human diets. The objective of this study was to characterize the nutrient concentrations in leaf, pod, and seed of faba bean varieties. A field study was conducted with six faba bean varieties. Variation in the elemental concentrations of nutrients and protein occurred among varieties and different parts of the plants. The highest concentrations of nitrogen, phosphorus, potassium, zinc, or copper and protein were in the seeds. However, the highest accumulation of calcium, magnesium, iron, or manganese was in the leaves. We recommend that faba bean can be considered as a valuable crop in the diet of nutrient-deficient consumers due to high concentration nutrients in edible parts of the plant.     

Potassium accumulation,partitioning, and remobilization in high-yield spring maize in Northeast China

Potassium (K) plays an important role in maize yield, but K accumulation characteristics in high yielding maize is still not well documented. A two-year field experiment was conducted to investigate the K accumulation characteristics of high yield (HY)（>15 t ha^?1）spring maize compared with medium yield (MY)（10–15 t ha^?1), and low yield (LY)（<10 t ha^?1). The maximum K accumulation stage in maize appeared between V6 and V12 stage (LY, MY, and HY was 125.46, 138.05, and 146.22?kg ha^?1, respectively). Most of the K (94.27–97.13%) was accumulated during vegetative stages. HY exhibited a significantly higher K accumulation than either MY or LY. For different organs, the K remobilization amount of leaf was the highest, and the remobilization amount of stalk was the lowest, the K remobilization amount of leaf and stalk showed as HY?<?MY?<?LY, same as the total K remobilization amount, but the K remobilization amount of sheath and husk plus cob showed the opposite order. These results indicated that sufficient nutrient supply for maize can not only accumulate more K but also delay leaf senescence and maintain high photosynthetic activity, resulting in reduced K remobilization from vegetative organs, and reduced K loss in whole plant.