在磁场中活性炭吸附有机物的研究

将磁化技术引入吸附过程中，考察了磁场处理对活性炭吸附苯、硝基苯、苯甲酸、氯苯和苯酚的影响．结果表明，预磁处理能使非极性物质苯和极性较小的氯苯、苯酚在活性炭上的吸附容量减小，而使极性较大的苯甲酸和有NO2基团的硝基苯的吸附容量增大．增大磁场强度能加强苯和苯甲酸的磁处理效果。     

污水处理厂剩余污泥对凤仙花和万寿菊生长的影响

采用盆栽方式,通过对花卉植物生长状况和各项生理指标的考察,研究了不同污泥施用比对凤仙花(Impatiens balsamina)和万寿菊(Tagetes erecta L.)生长的影响。结果表明,污泥施用比不高于5%(质量分数)时对两种花卉植物发芽有促进作用。在前期,对照组凤仙花和万寿菊生长较好,其株高、叶绿素和可溶性糖含量高于污泥施用组,丙二醛(MDA)含量低于污泥施用组。而在后期,污泥的施用对两种花卉生长促进作用明显,污泥施用组的两种花卉植物株高和各项生理指标优于对照组,尤其是开花状况显著好于对照组。凤仙花和万寿菊较优的污泥施用比分别为3%~5%和1%~5%。     

水中总氮空白的影响因素的探讨

本研究以水中总氮空白值为研究对象,不同厂家的过硫酸钾和不同试验用水条件下的总氮空白的变化规律。研究结果表明：无氨水和二次水蒸出来的总氮空白明显低于一次水蒸出来的总氮空白;这跟蒸馏水纯度有关系,一次水含有氨,所以消解时蒸馏水中的氨会被氧化,从而导致空白值偏高。同样有的厂家的过硫酸钾纯度不高,所以导致空白值高。     

从山东省部分行业看工业节水潜力

本文采用万元产值取水量和水重复利用率作为节水指标,通过对山东省主要工业行业用水节水现状进行调查研究,阐述了各行业节水水平和节水经验,分析并预测了节水潜力,总结提出了各行业应采取的主要节水措施和建议。     

一株多环芳烃降解菌的筛选及其降解特性

微生物修复是治理土壤多环芳烃(polycyclic aromatic hydrocarbons, PAHs)污染的主要方法,而高效降解菌筛选是微生物修复技术的重要基础。从北京焦化厂土壤中筛选分离得到一株PAHs降解菌Q3,通过生理生化和16S rDNA等分析手段鉴定其为Rhodococcus rhodochrous。结果表明:该菌株对芘的耐受能力较强,可降解初始浓度为200 mg·L~(-1)的芘;该菌株具有降解广谱性,可利用苯并[a]芘、苯并[b]荧蒽、二苯并[a,h]蒽、苯并[g,h,i]苝等9种PAHs为唯一碳源进行代谢,特别是对苯并[a]芘等高环PAHs具有较好的降解效果;此外,该菌株可有效降解模拟液中的混合PAHs,并且对野外被PAHs长期污染的土壤具有较好的强化修复效果。投加菌株处理后的处理组与对照组相比,土壤PAHs总去除率提高了24%。以上结果表明该菌株对环境中被PAHs污染的土壤具有较好的强化修复潜力,可为PAHs污染土壤的微生物修复技术提供技术参考。     

臭气浓度标准的制定方法

本文首先介绍了天津市恶臭污染物排放标准中臭气浓度标准制定的程序、方法、步骤及有关参数确定要素。并将天津市的臭气浓度排放标准与日本、美国及我国台湾省的同类标准进行了分析比较。     

虎纹蛙（RANA RUGULOSA）视网膜结构与环境适应性的研究

在光镜和电镜下观察了虎纹蛙（Rana rugulosa)视多膜的组织结构，着重探讨了色素细胞和视细胞的形态结构。视网膜中三个核层及两个网状层分布均匀，无中央凹。色素细胞内含有大量的脂滴、色素颗粒、髓样体和形状各异的溶酶体等。视细胞由视杆细胞和视锥细胞组成，视杆细胞占多数。在视网膜中央区，视杆细胞数与视锥细胞数之比为1：1；在周缘区，两者数量之比为3：1，视杆细胞外段呈高柱状，体积远远大于视锥细胞外段，肌样体内有大量的微管。视锥细胞外段呈矮锥形，椭圆体内有一球状小体。视细胞与节细胞数量之比为3．68：1。结果表明，虎纹蛙视网膜结构特征与其生活于田间、山涧等弱光环境和捕食习性是相适应的。图版1（图1－图10）表2参14     

Optimal regulation of N/P in horizontal sub-surface flow constructed wetland through quantitative phosphorus removal by steel slag fed

High concentration of nitrogen and phosphorus and imbalance of N/P can lead to the formation of water and the malignant proliferation of toxic microalgae. This study put forward the advanced nutrient removal with the regulation of effluent N/P as the core in order to restrain the eutrophication and growth of poisonous algae. According to the preliminary study and review, the optimal N/P for non-toxic green algae was 50:1. The horizontal sub-surface flow constructed wetland was filled with steel slag and ceramsite to achieve the regulation of effluent N/P. The results showed that steel slag had the stable P removal capacity when treating synthetic solution with low P concentration and the average removal rate for 1.5, 1.0, and 0.5 mg/L synthetic P solution was 2.98 ± 0.20 mg kg−1/h, 2.26 ± 0.15 mg kg−1/h, and 1.11 ± 0.10 mg kg−1/h, respectively. Combined with P removal rate and P removal task, the filling amount of steel slag along the SSFCW (sub-surface flow constructed wetland) was 3.22 kg, 4.24 kg, and 4.31 kg. In order to ensure the stability of dephosphorization of steel slag, the regeneration of P removal capacity was investigated by switching operation of two parallel SSFCW in 20 days for cycle. The N removal was limited for the deficiency of carbon source (COD (chemical oxygen demand)/TN = 3–4), and was stable at 18.5–31.9% which was less affected by temperature. Therefore, by controlling the process of quantitative P removal of steel slag, the effluent N/P in SSFCW can be stable at 40–60:1 in the whole year, so as to inhibit the malignant proliferation of toxic algae.     

嗅觉标准液的人群测试

嗅觉标准液是可使人的嗅觉阈值测试标准化，科学化，数量化，应用嗅觉标准液对人群的嗅觉阈值测试，可以了解我国人群嗅觉状及特点，以便应用标准液筛选嗅觉试验员和鼻科临床无创伤检验等方面。     

Decomposition of NO in automobile exhaust by plasma–photocatalysis synergy

The combination of plasma discharge and TiO₂ photocatalysis exhibits high performances in the removal of nitrogen monoxide (NO). This article is aimed at elucidating the relationships between NO decomposition efficiency and various experimental parameters, including voltages, humidity and temperature. The experimental results indicate that the efficiency of NO removal by synergic plasma-catalyst coupling is significantly higher than plasma only or photocatalyst only systems. Moreover, the NO removal efficiency improves with the increase of applied voltage. Meanwhile, a higher humidity results in a reduced number of electron–hole pairs at the surface of TiO₂ photocatalyst, leading to lower synergic purification efficiencies. Finally, the efficiency of NO removal is raised with the increase of temperature due to the fact that the adsorption of NO and water by nano-TiO₂ is affected by environmental temperature.