Ecological implications of motor oil pollution: Earthworm survival and soil health

The nontarget effects of fresh and used motor oil were studied in a soil test system involving such criteria as earthworm survival, response of soil dehydrogenase and urease, and nitrification. When earthworms were exposed to motor oil-contaminated soil for 4 weeks, the observed median lethal concentrations (LC₅₀) were 40.33 and 3.88 g kg⁻¹ soil for fresh and used oil, respectively. Only fresh motor oil application increased earthworms' body weight even at the higher dose of 19 g kg⁻¹ soil. Gas chromatography/mass spectrometry revealed that used motor oil contained more of aromatic hydrocarbons and heavy metals than fresh oil. This disparity in the chemical composition might be the factor responsible for the significant toxicity of used motor oil towards earthworms. Activities of soil dehydrogenase and urease were significantly enhanced in presence of both the motor oils, while there was a significant inhibition in nitrification by the used motor oil even at a low concentration of 0.2 g kg⁻¹ soil. This study clearly demonstrated that earthworm survival and nitrification could serve as suitable indices to assess motor oil pollution in soil.     

青藏高原东北部3种野豌豆植物学特性及资源储量

采用野外定点法、最小样方法和统计学方法对生长于青藏高原东北部的3种野豌豆属植物的植物学特性、生态环境、群落数量特征及资源储量进行研究。结果显示,救荒野豌豆、山野豌豆和三齿萼野豌豆的植物学特性、生态环境和群落数量特征具有一定差异,3种野豌豆在青海省的资源总储量分别为0.46×10~6、0.23×10~6、0.27×10~6 kg,表明3种野豌豆属植物的资源总量在青海省并不高,应对其进行有效的引种驯化,实现人工繁育和增加资源储量,这既可保护青海省甚至青藏高原的生态环境,也可对其资源进行有效地保护和合理开发利用。     

不同配比南极磷虾粉饲料对网箱养殖俄罗斯鲟生长及氟累积的影响

配制南极磷虾粉替代饲料中鱼粉比例分别为0%、10%、20%、30%的4组饲料饲喂俄罗斯鲟(Acipenser gueldenstaedtii)200 d后,分析南极磷虾粉替代部分鱼粉对网箱养殖俄罗斯鲟生长和鱼体组织氟残留的影响。结果表明:(1)随着南极磷虾粉替代比例的升高,俄罗斯鲟的末重、增重、特定生长率、蛋白质效率先上升后下降,饲料系数先降低后升高,10%组显著高于对照组和其它试验组(P0.05);(2)实验结束时,俄罗斯鲟肌肉、肝脏和鱼鳔的氟浓度低于检测限,但鳃、皮、脊骨和背骨呈现剂量浓度效应,各试验组较对照组显著升高(P0.05)。综上所述,在本实验条件下,在俄罗斯鲟饲料中加入10%比例的南极磷虾粉时获得最佳生长效果和较低的组织氟累积。     

锰胁迫下鸡眼草的富集特征及生理响应

为探明植物对锰胁迫的耐受性机制,以采自重金属污染区与非污染区的鸡眼草为试验材料,在不同锰浓度胁迫下［0 （对照）、1000、5000、10000、15000、20000 μmol·L^-1］ 开展盆栽试验,比较研究锰胁迫对两种来源鸡眼草表型、生理生化特性及锰积累特征的影响。结果表明：随着锰浓度的升高,1） 两种来源鸡眼草的根干重、芽干重、根冠比均呈降低的趋势;当锰浓度达5000~20000 μmol·L^-1时,与对照相比,污染区、非污染区鸡眼草的芽干重分别下降4.34%~27.71%与16.33%~49.77%,根干重分别下降19.00%~66.06%与27.90%~77.54%,污染区下降幅度均较非污染区的小;2） 两种来源鸡眼草的叶绿素、可溶性糖、脯氨酸含量及超氧化物歧化酶（SOD）、过氧化物酶（POD）活性均呈先升后降的趋势,可溶性蛋白含量逐渐下降,丙二醛（MDA）含量则逐渐升高;3） 两种来源鸡眼草根、茎、叶的锰含量均增加;锰浓度为20000 μmol·L^-1时,污染区和非污染区鸡眼草的叶锰含量分别为对照的16.53和13.41倍。因此,污染区鸡眼草锰耐受能力及富集能力均较非污染区鸡眼草高,较高的抗氧化酶活性是其耐受高锰胁迫的重要生理机制。     

水氮调控对苜蓿与无芒雀麦混播草地生长和辐射利用的影响

针对我国内陆干旱区人工草地生产管理粗放及气候资源利用不充分等问题,探究合理的牧草种植与水氮供应模式,以充分挖掘区域牧草的生产潜力。采用3 a生(2018年播种)紫花苜蓿(简称‘苜蓿’)和无芒雀麦,分析种植模式(苜蓿与无芒雀麦混播,D1;无芒雀麦单播,D2)、施氮量(低氮量N1:60 kg·hm^-2;高氮量N2:120 kg·hm^-2)和灌水量(以灌水下限占田间持水量θ_f的百分比计,分枝期均充分灌水(75%～85%θ_f),现蕾和初花期轻度亏水W1:65%～75%θ_f、中度亏水W2:55%～65%θ_f、重度亏水W3:45%～55%θ_f,灌水上限均为85%θ_f)对牧草叶面积指数(LAI)、干物质累积量、累积截获光合有效辐射量(CIPAR)、辐射利用效率(RUE)、产量(Y)、耗水量(ET_a)、水分利用效率(WUE)和氮肥偏生产力(PFP_N)的影响。结果表明：(1)牧草LAI和...     

引水渠道口门泥沙淤积计算

引水渠是一种常见的河道分流形式，由于主河道与引水渠之间往往有一定的夹角，水流从分汊前主河道流入引水渠时必然在一定的范围内发生一定程度的弯曲，其结果是有利于较多较粗的泥沙分入引水渠，导致渠道口门产生较为严重的淤积现象，而渠道口门淤积问题是决定引水工程是否成败的主要因素之一，通过一维非恒定流水沙沙数学模型，研究了不同水沙条件下引江济汉工程引水渠道口门泥沙淤积厚度变化规律，并分析了糙率对口门淤积厚度的影响情况，模型的计算结果与水流运动规律相吻合，可以为渠道引水防沙设计提供技术支持。     

设施桃对硒的吸收运转及积累特性的初步研究

本试验以设施栽培的4年生春雪毛桃（砧木为青州冬雪蜜桃）为试材,研究硒元素在桃中的吸收运转及积累特性,为设施桃富硒果品生产技术的提出提供理论依据。结果表明：从花后40d至80d,设施桃不同部位硒元素含量的变化趋势不同,其中叶片呈‘升-降-升（土施氨基酸硒）’与‘持续上升（叶面喷施氨基酸硒）’、果肉呈‘升-降’、果皮呈‘升-降（土施氨基酸硒）’和‘降-升-降（叶面喷施氨基酸硒）’、果核呈下降的变化趋势;设施桃从果实硬核至转色阶段是设施桃可食部分-果肉对硒元素吸收的活跃期;硒肥的施用方式不仅影响硒元素在果皮、果肉和果核及果肉和叶片等各部位的累积顺序,而且显著影响硒元素的利用效率,叶面喷硒的硒元素利用率远高于土壤根际施硒的硒元素利用率。综上,设施桃从坐果到果实成熟,采用叶面喷硒,尤其是加强果实硬核至果实转色阶段的施用,是设施桃富硒果品生产的关键措施。此外,抑制设施桃果实成熟前后新梢的补偿性生长是减轻或避免果实中硒元素外流的重要措施。     

茭虾共作对土壤氮磷含量和茭白干物质积累及氮磷钾吸收分配的影响

为探究茭白种养模式的施肥策略,设置茭虾共作（ZC）、茭白单作（Z） 2个处理,研究茭虾共作对土壤氮磷含量、茭白产量和茭白干物质积累及氮磷钾吸收分配的影响。2021-2022年的研究结果显示,茭虾共作模式较茭白单作模式采茭期土壤中全氮、全磷、速效磷的含量分别提高了10.85%~38.89%、5.45%~13.79%、6.19%~61.79%,净茭产量提高了5.10%~19.54%,采茭期茭白茎、叶、净茭的干物质积累量分别增加14.41%~16.58%、10.28%~15.15%、10.57%~21.45%。2021年茭虾共作处理较茭白单作处理在采茭期叶的氮含量显著增加了25.74%,但在孕茭期茎中磷含量显著减少了16.76%;2022年氮肥减量、减量投喂下,茭虾共作处理较茭白单作处理在孕茭期茎的氮含量显著减少了23.75%,在分蘖期叶中磷含量显著减少了12.08%,2 a全生育期同一器官的钾含量在2个处理间差异不显著。对于养分积累,2021年茭虾共作处理在分蘖期叶的氮、磷、钾积累量较茭白单作处理分别减少26.04%、27.27%、30.11%,但在采茭期茎的氮、钾积累量和叶的氮、磷积累量较茭白单作处理分别增加18.80%、38.41%和44.77%、35.71%;2022年在氮肥减量、饲料减量投喂下,茭虾共作处理在采茭期叶的磷积累量和茎的钾积累量较茭白单作处理显著增加30.0%和30.77%。关于养分分配,2种处理的茭白在孕茭期和采茭期氮素的分配均以茎、叶为主,而磷、钾元素的分配均以茎为主,茎分配比例在42%~66%。对于养分转运,2021年2种处理茭白的根、茎、叶在氮、磷转运上大多为表现为“库”器官,而在钾转运上大多表现为“源”器官;2022年氮肥减量、减量投喂下,茭白的根、茎、叶在氮、磷、钾转运量上大多表现为“源”器官。因此,在茭虾共作模式中适当减少肥料、饲料的投入,能促进形成合理的源库关系,有利于茭白产量的形成。     

Phosphorus saturation in soils and groundwaters

On average, crops require about 30 kg ha⁻¹ y⁻¹ of P in humid regions. in some regions fertilizer and manure are applied in amounts that exceed this. the surplus of P in agricultural areas is about 20-45 kg ha⁻¹ y⁻¹. This implies an accumulation of P. the surplus of P estimated from the balance of agricultural soils of industrialized countries in Europe in the last four decades is between 800 and more than 1500 kg ha⁻¹ although this distribution is not even. Phosphorus accumulation is more than one order of magnitude higher than average in areas with intensive livestock farming. Consequently, The application of high levels of manure exceed the capacity of the soil to store P. This implies that P saturation May, pose a problem. Indeed, about half of the Dutch sandy soils (approximately 300 000 ha) are currently considered to be saturated with P, meaning that there is a hazard of P leaching to groundwaters in the future. Assuming current phosphate application rates, phosphate leaching is a distinct possibility over a period of decades to a century. Vulnerable areas are soils with high inputs, low sorption capacities for P, high water-tables and a low retention time for water. the possible consequence is a time-delayed increase of eutrophication of surface waters (lakes, rivers and the sea) caused by a diffuse load of P in the few next decades. Modelling the influence of different agricultural strategies shows that accumulation of P would not increase further only if the use of P increases by an amount that compensates for the increased inputs. It is proposed to change the current support system of agriculture by installing a system of financial incentives and taxes which seek to promote nutrient balances for each farm.