普光气田应急指挥系统应急值守功能设计

应急值守作为应急指挥系统重要的组成部分,发挥着无可替代的作用。对普光气田应急指挥系统的应急值守功能进行了详细的介绍,包括日常值班、接警事件处理、预案关联及电话调度、自动录音、多方通话等。     

废手机面板焚烧产物研究

以废手机面板为试验材料,利用热重分析仪(TGA)研究热处理失重特征,同时利用气相色谱仪-质谱仪联用(GC-MS)对管式炉试验系统焚烧产物进行分析. 结果表明:废手机面板焚烧失重温度为128.3～558.1 ℃,最大失重温度为357.4 ℃;焚烧废手机面板导致面板组成材料液晶、偏光片和取向剂等发生化学反应,焚烧产物除CO₂外,还含有醛、酮、联苯酚、苯胺等芳香族化合物和少量的苯并吡喃、萘、菲、吡啶等多环芳烃(PAHs). 由于焚烧产物中绝大多数是有毒有害物质,部分可致癌,故废手机面板不宜焚烧处理,如与其他固体废物混合焚烧,必须采取相应的污染控制措施.      

电脑和手机电磁辐射强度测试及防护对策

测试了电脑显示器和手机工作时电磁辐射强度的大小,总结了它们发射电磁波强度大小的规律,并与国家标准进行了比较,针对电磁波的危害提出了一些防护措施和对策。     

固体超强酸SO4^2-／TiO2-SnO2／Ce^4＋光催化降解含酚废水

采用共沉淀-浸渍法制备了固体超强酸SO4^2-／TiO2-SnO2／Ce^4＋,并用XRD、SEM等方法对其结构进行了表征。以苯酚的光催化降解为反应模型,确定了最佳的工艺条件和催化剂再生方法。结果表明：在pH值为6,苯酚初始浓度为50mg／L,催化剂投加量4g／L,光照距离12cm,光照时间为150min,降解率达67．73％,添加助催化剂H2O2后,反应60min,苯酚降解率达到86．33％,催化剂的最佳再生方法是先用1mol／L的硫酸浸渍24h后,在450℃下焙烧6h。     

Fungicide tolerant Bradyrhizobium japonicum mitigate toxicity and enhance greengram production under hexaconazole stress

Bacterial strain RV9 recovered from greengram nodules tolerated 2400 μg/mL of hexaconazole and was identified by 16 S rDNA sequence analysis as Bradyrhizobium japonicum(KY940048). Strain RV9 produced IAA(61.6 μg/mL), ACC deaminase(51.7 mg/(protein·hr)), solubilized TCP(105 μg/mL), secreted 337.6 μg/mL EPS, and produced SA(52.2 μg/mL) and 2,3-DHBA(28.3 μg/mL). Exopolysaccharides produced by strain RV9 was quantified and characterized by SEM, AFM, EDX and FTIR. Beyond tolerance limit,hexaconazole caused cellular impairment and reduced the viability of strain RV9 revealed by SEM and CLSM. Hexaconazole distorted the root tips and altered nodule structure leading thereby to reduction in the performance of greengram. Also, the level of antioxidant enzymes, proline, TBARS, ROS and cell death was increased in hexaconazole treated plants.CLSM images revealed a concentration dependent increase in the characteristic green and blue fluorescence of hexaconazole treated roots. The application of B. japonicum strain RV9 alleviated the fungicide toxicity and improved the measured plant characteristics. Also,rhizobial cells were localized inside tissues as revealed by CLSM. Colonization of B.japonicum strain RV9 decreased the levels of CAT, POD, APX, GPX and TBARS by 80%, 5%,13%, 13% and 19%, respectively over plants grown at 80 μg/(hexaconazole·kg) soil. The ability to detoxify hexaconazole, colonize plant tissues, secrete PGP bioactive molecules even under fungicide pressure and its unique ability to diminish oxidative stress make B.japonicum an attractive choice for remediation of fungicide polluted soils and to concurrently enhance greengram production under stressed environment.