粮食损失研究进展和展望

我国人多地少,粮食安全事关国家安全。因此,在重视增产的同时,需要不断关注粮食损失问题。通过回顾现有粮食损失的研究,总结文献中提出的重要问题,展望未来可能的研究方向。分析表明,现有研究主要集中在：（1）减少粮食损失的目的和效果的研究。包括增加粮食供给、保障国家安全,减少不必要的资源浪费、减轻环境压力,保障粮食质量、保证食品安全,以及增加粮食价值链参与者的利润等。（2）粮食产后各环节损失水平估计及其影响因素研究。 （3）减少粮食损失的方法研究,包括品种改良、教育培训、改进储存设施等。在对现有研究综述的基础上,提出了几点展望：未来的研究应向粮食价值链下游环节拓展,对粮食质量损失程度进行定量分析,并关注粮食的最优损失水平。     

市县“双评价”中优势农业空间划定研究：理论、方法和案例

我国城镇化迅速蚕食宝贵的耕地资源和乡村聚落,保护基本农田、保护乡村、保护农业空间的需求迫在眉睫。新一轮市县国土空间规划“双评价”中,针对“农业空间”只重视基本农田和粮食生产的不足,旨在构建“优势农业空间”划定的理论框架和技术方法,为保护农林牧副渔大农业空间、全农业领域生产者和特色、重点农村地区奠定基础。（1）在生态保护极重要区以外,开展全域、全要素的种植业、畜牧业、渔业生产适宜性评价,识别农业生产适宜区和不适宜区;（2）基于高产稳产、规模经营和集中连片三原则,进一步细化评价重要经济作物适宜区、地域特色农产品适宜区等;（3）在此基础上,结合特色村落、重大农业基础设施要素识别优势农业空间。该技术框架在沈阳和温州市县“双评价”中取得了科学实用的评价成果,为我国正在展开的国土空间规划提供了科学支撑。     

剩余污泥深度干燥的研究进展

剩余污泥的含水率较高,对污泥进行干燥处理可以极大程度地减少污泥的水分。首先分析了污泥的含水特性和干燥污泥机理,然后分析了主要的污泥干燥方法研究现状,如热风干燥、过热蒸汽干燥、间接干燥、低温热流干燥、热泵干燥、太阳能干燥等。此外,探究了新型的污泥干燥技术及污泥干燥过程中可能产生的污染物,并在此基础上,对污泥干燥技术的发展方向进行了展望。     

Kinetic and mechanism studies of the ozonolysis of three unsaturated ketones

Reaction rate constants and products of 1-octen-3-one, 3-octen-2-one and 4-hexen-3-one with ozone were studied in a 100-L fluorinated ethylene propylene (FEP) Teflon film bag using absolute rate method at 298 ± 1 K and atmospheric pressure. The rate constants were (1.09 ± 0.12) × 10^?17, (3.48 ± 0.36) × 10^?17 and (5.70 ± 0.60) × 10^?17 cm³/(molecule?sec), respectively. According to the obtained rate constants, the effects of carbonyl were discussed. The carbonyl group in β position has a net withdrawing effect with respect to an olefinic bond, then causing the decline of rate constants. The quantum chemical calculation was used to explain the results of rate constants. The products of ozonolysis were mainly aldehydes, which have significant influence on the formation of SOA, and hence play an important role in the atmosphere. In this work, we detected the main products of reaction and proposed the reaction mechanism by combining the results of quantum chemical calculations. Atmospheric lifetime for three unsaturated ketones reacted with ozone was 36.4, 11.4 and 6.9 hr for 1-octen-3-one, 3-octen-2-one and 4-hexen-3-one, respectively.     

Optimized photocatalytic regeneration of adsorption-photocatalysis bifunctional composite saturated with Methyl Orange

Photo-responsive adsorption-photocatalysis nanocomposites are generally used in water and wastewater decontamination; however, the prolonged adsorption capacity of composites and the role of adsorption in concomitant photocatalysis are typically neglected. These composites can be regenerated under light irradiation as their adsorption capacity decreases. Herein, a novel adsorption-photocatalysis bifunctional nanocomposite, Bi-doped TiO₂ supported on powdered activated carbon (Bi₂O₃/TiO₂/PAC), was prepared using the sol-impregnation-hydrothermal procedure. Bi₂O₃/TiO₂/PAC with a secondary calcination temperature of 700°C under a nitrogen atmosphere was selected for maximum adsorption capacity on Methyl Orange (MO). The composite displayed an excellent adsorption capacity and was easily separated and recycled. The results demonstrate that 71.2% photocatalytic regeneration efficiency could be attained under visible light irradiation for 1 hr at an intensity of 750?W/m² and pH 7. Characterization of the as-prepared Bi₂O₃/TiO₂/PAC nanocomposite (700°C) indicates that it possesses a highly specific surface area and great optical properties, showing bifunctional adsorption-photocatalysis characteristics. The p-n heterojunction of the composite played a dominant role in the photocatalytic regeneration process, and effective degradation of MO could be achieved along with composite regeneration.     

Surface characterization of metal oxides-supported activated carbon fiber catalysts for simultaneous catalytic hydrolysis of carbonyl sulfide and carbon disulfide

The sol–gel method was used to synthesize a series of metal oxides-supported activated carbon fiber (ACF) and the simultaneous catalytic hydrolysis activity of carbonyl sulfide (COS) and carbon disulfide (CS₂) at relatively low temperatures of 60°C was tested. The effects of preparation conditions on the catalyst properties were investigated, including the kinds and amount of metal oxides and calcination temperatures. The activity tests indicated that catalysts with 5 wt.% Ni after calcining at 400°C (Ni(5)/ACF(400)) had the best performance for the simultaneous catalytic hydrolysis of COS and CS₂. The surface and structure properties of prepared ACF were characterized by scanning electron microscope-energy disperse spectroscopy (SEM-EDS), Brunauer–Emmett–Teller (BET), X-ray diffraction (XRD), carbon dioxide-temperature programmed desorption (CO₂-TPD) and diffuse reflectance Fourier transform infrared reflection (DRFTIR). And the metal cation defects were researched by electron paramagnetic resonance (EPR) method. The characterization results showed that the supporting of Ni on the ACF made the ACF catalyst show alkaline and increased the specific surface area and the number of micropores, then improved catalytic hydrolysis activity. The DRFTIR results revealed that -OH species could facilitate the hydrolysis of COS and CS₂; -COO and -C–O species could facilitate the oxidation of catalytic hydrolysate H₂S. And the EPR results showed that high calcination temperature conditions provide more active reaction center for the COS and CS₂ adsorption.     

SWAT模型在我国流域水环境模拟应用中的评估验证过程评价

模型评估验证是模型开发和应用过程中的重要环节,是管控模型应用于管理决策风险的重要手段.近年来,以SWAT模型为代表的流域水环境模型在我国流域水环境管理中得到广泛应用,但模型评估验证过程尚缺乏规范性指导.结合SWAT模型建模过程和模型评估验证的基本步骤,梳理总结SWAT模型评估验证过程的评价方法,针对确定研究或决策目标、获取输入数据、构建模型、模型率定验证、展示模型结果等5个阶段分别设计评价指标.筛选中国知网收录的2015—2017年发表的以SWAT模型为主题的428篇学术论文作为研究对象,评价现有研究的模型评估验证过程,分析我国SWAT模型评估验证的现状以及存在的问题和不足.评价结果表明,我国现有的SWAT模型应用研究总体比较重视模型评估验证过程,能够清晰定义研究区域、建模目标和期望产出,说明输入数据来源和质量以及模型概化、参数灵敏度分析、参数识别、不确定性分析的方法和结果,模型模拟效果较好.但是,针对SWAT模型评估验证方法的研究较少,在模型参数识别方面还存在参数选取未考虑研究区域特征、参数识别结果不合理等问题.建议在SWAT模型应用研究中关注参数灵敏度分析和参数识别,结合研究区域特征建立本地化应用数据库,加强模型评估验证方法研究.当模型应用于流域水环境管理决策时,应完整地开展模型评估验证,并分析模型不确定性对决策的影响.      

叶菜类蔬菜产地镉环境质量类别划分技术研究

以农业农村部环境监测总站对我国主要叶菜类蔬菜产地的例行监测数据为基础,综合考虑种类和土壤理化性质的影响,深入探讨了应用物种敏感性分布法（SSD）基于不同累积概率建立我国叶菜类蔬菜产地“优先保护类、安全利用类和严格管控类”的土壤镉环境质量类别划分阈值,并对其合理性验证.结果表明：pH值、阳离子交换量（CEC）和土壤有机质（SOM）对叶菜类蔬菜富集镉的影响均达到了极显著水平（P<0.01）,并由其构建的三因子生物有效性模型为lgBCF=-0.122pH+0.025lgSOM-0.048lgCEC+1.252（R²=0.746,P<0.01,n=134）,可解释叶菜类蔬菜富集系数74.6%的变异;利用上述模型将不同土壤理化性质条件下叶菜类蔬菜镉的生物富集系数（BCF）归一化处理可最大程度降低土壤理化性质对其富集镉的影响,凸出叶菜类蔬菜的内在敏感性;利用归一化后的BCF通过log-logistic拟合函数构建SSD曲线得到,不同叶菜类蔬菜种类对镉的敏感性差异明显;依据SSD曲线基于保护80%、50%和5%的叶菜类蔬菜种类分别推导出pH≤6.5、6.5相似文献   

紫外线对再生水中斜生栅藻的生长抑制效果

再生水具有就近易得、水量大且稳定等突出优点,已成为景观水体的重要补给水源。但再生水中含有氮、磷等营养物质,景观回用过程中可能会加剧藻类水华爆发风险。在藻类生长的早期阶段,采用紫外线处理有可能将再生水中藻类生物量控制在低风险范围,从而预防再生水景观回用水体中发生水华。以深圳市某污水处理厂二级出水为再生水回用景观水体的典型样品,考察了紫外线（254 nm波段）对典型微藻斜生栅藻的生长抑制效果,采用流式细胞术、调制荧光技术等方法,研究了不同紫外剂量对斜生栅藻的生长抑制效果,以及对藻细胞膜完整性和光合活性的影响。结果表明:对于初始密度约为7×104个/mL的斜生栅藻,50~100 mJ/cm2的紫外线能够取得1~5 d的生长抑制期,150~200 mJ/cm2剂量能将生长抑制期延长至10 d。紫外线能迅速引起斜生栅藻光合活性下降并能逐渐引起部分藻细胞破裂,100~200 mJ/cm2剂量处理后10 d内膜损伤细胞比例达到16%~71%。可见,紫外线能够对再生水中的斜生栅藻取得显著的生长抑制效果,是具有应用前景的景观水体水华风险防控手段。     

基于电场控制的SMP与EPS分布和迁移

将微生物燃料电池（MFC）与膜生物反应器（MBR）进行耦合,构建了MFC-MBR一体化系统。基于MFC-MBR一体化系统,研究分析了MFC微电场对MBR膜组件周围溶解性微生物代谢产物（SMP）和胞外聚合物（EPS）的分布和迁移的影响。研究结果表明:MFC-MBR一体化系统可提供的最大输出电压为0.78 V。在此电场作用下,MBR的跨膜压差（TMP）达到30 kPa所需时间为14 d,比无外加电场所用时间长6 d。与此同时,扫描电镜显示:在长期运行后,有电场情况下,膜表面覆盖物较无电场少。通过对MBR膜组件周围SMP与EPS进行检测分析,发现在外加电场作用下,SMP与松散胞外聚合物（LB-EPS）会远离膜组件,其浓度会随着与膜组件距离的增加而增大;而紧密胞外聚合物（TB-EPS）不受电场影响,呈均匀分布状态。此外,SMP与LB-EPS在微电场作用下能够进行远离MBR膜表面的定向移动,从而可以有效减缓MBR膜污染,为MBR降低运行成本提供参考。