湖岸缓冲带反硝化作用的研究进展

反硝化作用是湖岸缓冲带去除硝酸盐的重要途径。湖岸缓冲带是联系陆地与湖泊生态系的纽带,不仅为许多动植物提供适宜生境,而且通过反硝化作用能去除地下水中的硝酸盐,提高湖泊水质。概述不同检测反硝化速率的方法,并对比各种方法的优点与缺点。阐述反硝化作用的影响因素：厌氧环境、有机碳、湖岸坡度、缓冲带坡度、pH与温度、硝酸盐浓度。介绍反硝化速率模型的研究开发状况。最后,提出了目前国内外反硝化研究中存在的不足及发展方向。     

热处理天然褐铁矿制备γ-Fe2O3及其NH3-SCR活性探究

以天然褐铁矿为前驱体,通过热处理制备γ-Fe_2O_3作为NH3-SCR催化剂.借助XRD、XRF、XPS、NH3-TPD、FR-IR等表征方法,考察反应温度、褐铁矿中的锰氧化物以及H_2O和SO_2对催化剂选择催化还原NO活性的影响并与α-Fe_2O_3作对比.结果表明,由于γ-Fe_2O_3表面比α-Fe_2O_3具有更强的酸性,使得γ-Fe_2O_3的脱硝温度窗口(200~350℃)宽于α-Fe_2O_3(200~300℃),且在活性温度窗口下,催化剂脱硝效率达到99%以上;γ-Fe_2O_3催化剂中少量MnO_2的存在,提高了催化剂低温段(100~200℃)脱硝活性,降低了高温段(400~450℃)脱硝活性;SO_2的存在会使γ-Fe_2O_3的脱硝温度窗口向高温区偏移100℃、体积分数为5%的H_2O对脱硝反应的抑制作用很小,但当SO_2和5%H_2O同时存在,尤其是SO_2的体积分数达到0.12%时,硫酸铵盐类的迅速生成会大大降低γ-Fe_2O_3的脱硝活性;此外,γ-Fe_2O_3经过NH3-SCR反应后,其磁化率略有降低,催化剂仍然具有磁回收循环利用的潜力.     

太湖底泥疏浚的水环境质量风险性分析

采用基于因子分析的主成分分析法将五里湖的16个水质参数概括为5个主成分,研究了各主成分以及其综合主成分在疏浚前后的变化,并以此为依据就底泥疏浚对水环境质量的影响进行了评价.结果表明,疏浚过程中,五里湖疏浚区的综合主成分得分最高,为1.15,水质综合排名在最后,水体色度和污染指数(F1)也达到最高值5.0;同时对照区综合主成分得分以及水体污染和色度指数(F1,F2)也相应升高,水质质量明显下降;这说明疏浚运作具有促进表层沉积物发生再悬浮和扩散作用,以及沉积物中内源性营养盐和重金属离子的释放作用.采用Monte Carlo随机采样法,利用平衡分配模型模拟和预测了疏浚过程中悬浮沉积物中重金属离子释放的阈值,结果表明疏浚过程中大部分重金属离子由悬浮沉积物向水体中释放的风险性较高,可信度达到90%以上,尤其是重金属离子Ni²⁺以及非金属污染物As释放的风险性较大,其可能的释放量分别分布在各自地表水环境质量标准EQS的28.6%～+∞之间和34%～+∞之间,说明底泥疏浚具有导致五里湖水体环境质量短期恶化的风险.此外,Monte Carlo随机采样分析方法应用也许可为湖泊底泥疏浚生态风险评价提供一条新的途径.     

船用钢板材料在淡水环境中初期腐蚀行为

目的研究船用钢板材料在长江淡水环境中的初期腐蚀行为。方法运用形貌分析、腐蚀质量损失、XRD、开路电位、极化曲线等方法研究Q235B和CCSA两种船用钢板材料在室外长江淡水环境中不同暴露方式(水面大气、半浸、全浸)及不同浸泡时间(0.5,1 a)腐蚀行为;室内长江淡水环境不同暴露方式(半浸、全浸)浸泡768 h内的腐蚀行为;室内长江淡水环境全浸泡下在不同时间(0~14 d)的电化学腐蚀行为。结果两种船用钢板材料在武汉长江淡水中腐蚀严重,半浸泡环境下腐蚀速率最大,达到100μm/a,水面区大气腐蚀速率最小,腐蚀速率为30μm/a左右,全浸区腐蚀速率为80μm/a左右,1 a和0.5 a的腐蚀速率相近,CCSA耐蚀性优于Q235B。室内长江淡水浸泡环境下两种船用钢板材料腐蚀电位随时间而降低,2d后趋于稳定;半浸泡环境下腐蚀速率大于全浸区;极化曲线说明浸泡2 d后,腐蚀速率降低且趋于稳定。结论 CCSA耐蚀性优于Q235B,半浸泡环境下腐蚀最严重,其次为全浸区,水面大气环境腐蚀最小。     

陕南水镁石纤维的环境安全性评估

纤维水镁石在动物体内有一定的生物活性,但在人群流行性病学结果上显示的一系列信息如接尘工人只出现低的尘肺患病率,没有矽肺病和Ⅲ期尘肺患者。溶解性试验结果表明：水镁石纤维粉尘极易溶解在有机无机强弱酸、混合酸、有机无机铵盐、缓冲溶液中,也可部分溶于水中,导致其在体内滞留时间短且易于清除。说明水镁石纤维是安全的纤维材料且没有致瘤协同作用,由于矿物的表面/界面特征是除纤维特性以外控制纤维生物活性和危害性的关键因素之一,提出了矿物粉尘环境安全评价分类体系应突破矿物种的局限而深入到表面/界面的水平。     

亚铵法制浆造纸厂中段废水处理技术分析研究

通过对采用两级气浮做预处理 ,生物硫化床串联接触氧化做深度处理的治理技术的分析研究 ,结合废水处理工程实例 ,说明了用两级串联气浮 +硫化床 +接触氧化工艺处理造纸中段水技术切实可靠 ,该治理工艺对处理亚铵法麦草制浆造纸中段废水有较强的针对性和可行性。     

火电汽轮机组热电解耦技术研究

针对供热机组受传统“以热定电”运行模式限制,单机调峰能力低(最大仅有50%),无法满足深度调峰的问题,以国电集团西北地区所辖火电供热机组的实际运行情况为出发点,结合汽轮机组节能诊断及机组改造经验,提出了高、低压旁路联合供热,低压缸切缸运行两种热电解耦技术方案,通过比选得出两种技术方案的优缺点及适用范围。     

Grazing greatly reduces the temporal stability of soil cellulolytic fungal community in a steppe on the Tibetan Plateau

Excessive livestock grazing degrades grasslands ecosystem stability and sustainability by reducing soil organic matter and plant productivity. However, the effects of grazing on soil cellulolytic fungi, an important indicator of the degradation process for soil organic matter, remain less well understood. Using T-RFLP and sequencing methods, we investigated the effects of grazing on the temporal changes of cellulolytic fungal abundance and community structure in dry steppe soils during the growing months from May to September, on the Tibetan Plateau using T-RFLP and sequencing methods. The results demonstrated that the abundance of soil cellulolytic fungi under grazing treatment changed significantly from month to month, and was positively correlated with dissolved organic carbon (DOC) and soil temperature, but negatively correlated with soil pH. Contrastingly, cellulolytic fungal abundance did not change within the fencing treatment (ungrazed conditions). Cellulolytic fungal community structure changed significantly in the growing months in grazed soils, but did not change in fenced soils. Grazing played a key role in determining the community structure of soil cellulolytic fungi by explaining 8.1% of the variation, while pH and DOC explained 4.1% and 4.0%, respectively. Phylogenetically, the cellulolytic fungi were primarily affiliated with Ascomycota (69.65% in relative abundance) and Basidiomycota (30.35%). Therefore, grazing substantially reduced the stability of soil cellulolytic fungal abundance and community structure, as compared with the fencing treatment. Our finding provides a new insight into the responses of organic matter-decomposing microbes for grassland managements.     

Using geographically temporally weighted regression to assess the contribution of corruption governance to global PM2.5

Environmental Science and Pollution Research - In the face of the global haze crisis, exploring the driving force of political factors for controlling minute atmospheric particles has become...     

Urinary metabolomic profiling in rats exposed to dietary di(2-ethylhexyl) phthalate (DEHP) using ultra-performance liquid chromatography quadrupole time-of-flight tandem mass spectrometry (UPLC/Q-TOF-MS)

Di(2-ethylhexyl) phthalate (DEHP) is an omnipresent environmental chemical with widespread nonoccupational human exposure through multiple ways. Although considerable efforts have been invested to investigate mechanisms of DEHP toxicity, the key metabolic biomarkers of DEHP toxicity remain to be identified. The aim of this study was to assess the urinary metabonomics of dietary DEHP in rats using the technique of ultra-performance liquid chromatography quadrupole time-of-flight tandem mass spectrometry (UPLC/Q-TOF-MS). Fourteen female Wistar rats were divided into two groups and given increasing dietary doses of DEHP for 30 consecutive days. The urinary metabolite profile was studied using ultra-performance liquid chromatography coupled with quadrupole time-of-flight tandem mass spectrometry. Principal component analysis (PCA) and partial least squares-discriminant analysis (PLS-DA) enabled clusters to be clearly separated. Eleven principal urinary metabolites were identified as contributing to the clusters. The clusters in the positive electrospray ionization (ESI) mode were xanthurenic acid, kynurenic acid, nonate, N6-methyladenosine, and L-isoleucyl-L-proline. The clusters in the negative ESI mode were hippuric acid, tetrahydrocortisol, citric acid, phenylpropionylglycine, cPA(18:2(9Z, 12Z)/0:0), and LysoPC(14:1(9Z)). The urinary metabonomic changes indicated that exposure to dietary DEHP can affect energy-related metabolism, liver and renal function, fatty acid metabolism, and cause DNA damage in rats. The findings of this study on the urinary metabolites and metabolic pathways of DEHP may form the basis for future studies on the mechanisms of toxicity of this commonly found environmental chemical.