改性介孔托贝莫来石吸附水中U(VI)的性能及机理研究

以废弃粉煤灰和电石渣为原料,利用水热法制备了托贝莫来石(tobermorite,TOB),经热活化和酸化制得改性托贝莫来石(modify tobermorite,STOB)。实验结果表明,改性后,TOB的钙氧八面体晶体结构受到破坏,形成了更多的微孔和介孔,因此STOB的比表面积和孔容显著增加。在pH为5、温度为303 K、反应时间为60 min时,STOB对U(VI)的吸附率为91.72%,比TOB的吸附率提高了22.27%。干扰离子对STOB吸附U(VI)的影响最显著,这是由于STOB缺少与铀相关的特异性官能团,导致其他重金属离子与U(VI)争夺材料的吸附点位。此外,pH也对实验结果有一些影响,酸性越高,STOB吸附性能越差。STOB对U(VI)的吸附等温线与Dubinin-Radushkevich和Langmuir等温模型相吻合,且STOB对U(VI)的吸附行为符合准二阶动力学模型,表明吸附主要发生在表面,并且是以单层为主的化学反应。热力学参数揭示,U(VI)的吸附是一个吸热的自发过程,其吸附量和去除率随着吸附温度的增加而提高。在经过5次循环使用后,U(VI)的去除效率仍能保持在64.65%以上。

粪产碱杆菌改性生物炭对水中U(VI)的去除性能与机理

制备了粪产碱杆菌改性猪粪生物炭(PMBC-A1、PMBC-A2、PMBC-A3)用于去除水中的铀。扫描电镜和能谱仪表征表明粪产碱杆菌被分泌的生物膜包埋固定在生物炭表面,并形成了高磷界面。批次试验表明PMBC-A2对铀的吸附性能更优异,且不易发生磷污染。当U(VI)初始质量浓度为5 mg/L时,PMBC-A2最佳的吸附条件是投加量为0.1 g/L,温度为30℃,反应时间为24 h,此时对铀的去除率最高达92.65%。PMBC-A2除铀过程符合拟二级动力学模型和Langmuir等温线模型,拟合最大吸附容量为338.52 mg/g。在干扰离子存在时PMBC-A2对铀的吸附具有良好的选择性。吸附—解吸试验表明PMBC-A2具有循环利用的潜力。傅里叶红外光谱、光电子能谱和X射线衍射等表征证明PMBC-A2对水中铀的去除机理主要是磷酸基团和羧基的表面络合吸附、生物磷酸盐矿化和生物还原。

Reduction of Cr(Ⅵ) with a relative high concentration using different kinds of zero-valent iron powders: Focusing on effect of carbon content and structure on reducibility

Reduction of Cr(VI)using zero-valent iron(ZVI)could not only decrease the amounts of chemicals used for reduction,but also decrease the discharge of sludge.In order to find a desirable ZVI material,reduction of Cr(VI)with a relative high concentration using different kinds of ZVI powders(mainly carbon differences)including reduced Fe,grey cast iron,pig iron,nodular pig iron was carried out.Parameters such as ZVI dosage,type and size affecting on Cr(VI)reduction were firstly examined and grey cast iron was selected as a preferable reducing material,followed by pig iron.Additionally,it was found that the parameters had significant influences on experimental kinetics.Then,morphology and composition of the sample before and after reaction were characterized by SEM,EPMA and XPS analyses to disclose carbon effect on the reducibility.In order to further interpret reaction mechanism,different reaction models were constructed.It was revealed that not only the carbon content could affect the Cr(VI)reduction,but also the carbon structure had an important effect on its reduction.

ANALYTICAL SOLUTIONS TO STRESS CONCENTRATION PROBLEM IN PLATES CONTAINING RECTANGULAR HOLE UNDER BIAXIAL TENSIONS

The stress concentration problem in structures with a circular or elliptic hole can be investigated by analytical methods. For the problem with a rectangular hole, only approximate results are derived. This paper deduces the analytical solutions to the stress concentration problem in plates with a rectangular hole under biaxial tensions. By using the U-transformation technique and the finite element method, the analytical displacement solutions of the finite element equations are derived in the series form. Therefore, the stress concentration can then be discussed easily and conveniently. For plate problem the bilinear rectangular element with four nodes is taken as an example to demonstrate the applicability of the proposed method. The stress concentration factors for various ratios of height to width of the hole are obtained.

Assessment of UAV Based Vegetation Indices for Nitrogen Concentration Estimation in Spring Wheat

Unmanned Aerial Vehicles (UAVs) have become increasingly popular in recent years for agricultural research. High spatial and temporal resolution images obtained with UAVs are ideal for many applications in agriculture. The objective of this study was to evaluate the performance of vegetation indices (VIs) derived from UAV images for quantification of plant nitrogen (N) concentration of spring wheat, a major cereal crop worldwide. This study was conducted at three locations in Idaho, United States. A quadcopter UAV equipped with a red edge multispectral sensor was used to collect images during the 2016 growing season. Flight missions were successfully carried out at Feekes 5 and Feekes 10 growth stages of spring wheat. Plant samples were collected on the same days as UAV image data acquisition and were transferred to lab for N concentration analysis. Different VIs including Normalized Difference Vegetative Index (NDVI), Red Edge Normalized Difference Vegetation Index (NDVIred edge), Enhanced Vegetation Index 2 (EVI2), Red Edge Simple Ratio (SRred edge), Green Chlorophyll Index (CIgreen), Red Edge Chlorophyll Index (CIred edge), Medium Resolution Imaging Spectrometer (MERIS) Terrestrial Chlorophyll Index (MTCI) and Red Edge Triangular Vegetation Index (core only) (RTVIcore) were calculated for each flight event. At Feekes 5 growth stage, red edge and green based VIs showed higher correlation with plant N concentration compare to the red based VIs. At Feekes 10 growth stage, all calculated VIs showed high correlation with plant N concentration. Empirical relationships between VIs and plant N concentration were cross validated using test data sets for each growth stage. At Feekes 5, the plant N concentration estimated based on NDVIred edge showed one to one correlation with measured N concentration. At Feekes 10, the estimated and measured N concentration were highly correlated for all empirical models, but the model based on CIgreen was the only model that had a one to one correlation between estimated and measured plant N concentration. The observed high correlations between VIs derived from UAV and the plant N concentration suggests the significance of VIs deriving from UAVs for within-season N concentration monitoring of agricultural crops such as spring wheat.

不溶性腐殖酸对U(VI)的吸附动力学和吸附热力学

以不溶性腐殖酸(Insolubilized Humic Acid,IHA)为吸附剂,去除废水中的U(VI)。通过静态吸附试验,考察了p H值、时间、U(VI)初始质量浓度和温度等对吸附的影响,分析了吸附过程的动力学、热力学及等温吸附规律,并用红外光谱(FT-IR)和扫描电镜(SEM)分析了吸附机理。结果表明:35℃下1.4 g/L的IHA在p H值为5时对10mg/L U(VI)的去除率可达99.37%;IHA对U(VI)的吸附是自发的、放热的反应,符合Freundlich等温吸附方程,决定系数达0.99以上;吸附动力学过程符合准二级吸附速率方程,决定系数为1;IHA吸附U(VI)后表面形态发生了变化,与U(VI)相互作用的基团主要是羧基和酚羟基,综合看来,IHA吸附U(VI)的机理表现为离子交换。

壳聚糖插层膨润土的制备及其对U(VI)的吸附

以钠基膨润土为原料、壳聚糖为插层材料,制备了壳聚糖插层膨润土(CS-Bent),用于去除废水中的U(VI)。考察了p H、吸附剂投加量、U(VI)初始含量和吸附时间对CS-Bent吸附U(VI)的影响。结果表明,当温度为25℃,p H为6,CS-Bent投加量为1.6 g/L时,吸附平衡时间为60 min,对U(VI)的最大吸附量可达59.52 mg/g。Langmuir等温吸附模型和准2级动力学模型均可较好地拟合其吸附过程。X-射线衍射分析表明壳聚糖已经成功插入膨润土层间,傅里叶变换红外光谱、扫描电镜分析表明CS-Bent成功吸附U(VI)。以0.1 mol/L的HCl溶液作为解吸液,经过5次解吸后去除率仍有90%以上,表明CS-Bent可再生,具有较好的重复利用性。

奥奈达希瓦氏菌MR-1还原U(VI)的特性及影响因素

探讨了在腐殖质模式物蒽醌-2-磺酸钠(AQS)存在条件下,奥奈达希瓦氏菌MR-1的还原U(VI)特性.结果表明,在厌氧环境下奥奈达希瓦氏菌以AQS为电子穿梭载体,利用电子供体高效还原U(VI).当菌体投加量为1.2×109个时,其还原铀的效率达95.09%;AQS的浓度低于0.5mmol/L时有利于MR-1菌厌氧还原U(VI),AQS浓度的升高U(VI)的还原明显受到抑制.当U(VI)初始浓度为30.0mg/L时,分别以甲酸盐、乙酸盐和乳酸盐为电子供体,经过7d后其还原率分别达到95.37%、92.41%和95.65%.金属离子(Cu2+、Mn2+、Ca2+)、有毒有机物等对U(VI)还原产生影响.当Ca2+的浓度为2.0mmol/L时,对U(VI)的还原有微弱的促进作用,而当Cu2+和Mn2+浓度为2.0mmol/L时,则存在较强的抑制作用.奥奈达希瓦氏菌也能利用环境中甲苯、三氯乙酸、顺丁烯二酸等有毒物质高效还原U(VI),同时使有毒物质得到降解.扫描电子显微镜(SEM)和电子能谱(EDS)分析结果表明,奥奈达希瓦氏菌菌体中沉积了铀元素.

聚磷菌协同生物炭对水中U(VI)的去除特性及机理研究

低浓度含铀废水中铀的高效去除是铀矿冶安全生产过程中亟待解决的问题。生物吸附法是处理较低浓度重金属废水的高效廉价的方法之一。采用生物炭负载聚磷菌,制备了一种新型吸附剂,通过对比分析普通生物炭与负载聚磷菌生物炭对水中U（VI）的去除特性,结合BET、SEM及XPS等检测手段,考察聚磷菌对生物炭去除水中U（VI）的协同作用,探究低浓度铀废水处理新方法。结果表明,通过负载聚磷菌,生物炭能够快速降低水中U（VI）的浓度,去除率可达99.86%。BET及SEM表征手段表明,聚磷菌被固定在生物炭表面,负载聚磷菌的生物炭比表面积大大减小,但对铀的去除率反而增加。结合XPS结果可知,吸附后沉淀产物为四价铀和六价铀的混合物,表明聚磷菌对水中铀进行了还原、微沉淀,具有协同生物炭除铀作用。吸附动力学试验表明,该吸附过程符合准二级动力学模型;Freundlich吸附等温线模型能更好地描述吸附剂对铀的吸附行为。

U(VI) reduction by Shewanella oneidensis mediated by anthraquinone-2-sulfonate

Anthraquinone-2-sulfonate（AQS） was employed in humus substitutes to evaluate the effects and influencing factors of U（VI） reduction by Shewanella oneidensis MR-1（S. oneidensis MR-1） under anaerobic condition. The removal rate of U（VI） at 30 °C reaches 99.0% afterd 96 h with the p H value of 7.0 and AQS concentration of 1.0 mmol/L. The effective concentrations of AQS as the accelerator for U（VI） bioreduction are approximately 0.5-1.0 mmol/L. The bioreduction of U（VI） is inhibited when the concentration of AQS exceeds 2.0 mmol/L. The coexistence of ions, such as Cu2＋, Cr6＋, Mn2＋, shows a remarkable negative effect on the U（VI） reduction, and Zn2＋ shows less influence on the process compared with other tested ions. The U（VI） reduction is remarkably inhibited when the concentration of nitrate ion exceeds 1.0 mmol/L. Otherwise, no difference is found when the nitrate ion concentration is less than 0.5 mmol/L. Sulfate ion（5.0 mmol/L） slightly promotes the U（VI） reduction. Zero-valent iron（ZVI） promotes the U（VI） reduction by S. oneidensis, and the reduction rate improves with increasing the amount of ZVI in the range of 0-2.0 g/L. The XPS result indicates that uranium deposits on the cell surface are in U（VI） and U（IV） forms, and the majority of uranium in the solution is stable UO2.

零价铁吸附-还原溶液中U(VI)的实验研究

研究零价铁(Zero-valent iron,ZVI)去除溶液中的U(VI),分析了pH值、反应时间、ZVI投加量、铀溶液初始浓度、其它离子(Mg2+、Mn2+、Cl-、NO-3、CO2-3和Cu2+)等条件因素对U(VI)去除效果的影响,并讨论其去除机理。结果表明:ZVI对溶液中U(VI)有较好的去除作用,在pH=4,振荡时间为120min,ZVI投加量为1.6g/L,铀溶液初始浓度为10mg/L,铀去除量为4mg/g时,U(VI)的去除率可达到63.7%。其它离子实验结果表明:Mg2+、Mn2+、Cl-、NO-3对ZVI去除U(VI)影响不超过3%,CO2-3和Cu2+影响相对较大。ZVI去除溶液中U(VI)以还原沉淀和吸附作用为主,吸附-还原反应遵循一级化学反应动力学方程。

去除U(VI)的微生物组合构建及培养条件的优化

[目的]为了筛选U(VI)的抗性微生物及建立高效去除U(VI)的微生物组合。[方法]通过单菌株与混合菌株对U(VI)的抗性比较,采用正交试验对微生物组合的培养条件进行优化。[结果]除考式玫瑰菌外,XJ1、耐辐射奇球菌、柠檬酸杆菌3种微生物均能耐受50mg/L U(VI),其中耐辐射奇球菌和柠檬酸杆菌对30 mg/L U(VI)的去除率分别达到80.4%和84.8%;与单菌株对U(VI)的抗性相比,柠檬酸杆菌-耐辐射奇球菌组合对U(VI)的抗性有明显的促进作用。最佳条件为p H 6.0、温度30℃、U(VI)初始浓度10 mg/L,该组合对U(VI)的去除率可达到98.3%。[结论]筛选的微生物组合及其培养条件的优化可为微生物修复核素提供理论依据。

取代环戊二烯基铬、钼或钨羰基物UV－Vis的研究

取代环戊二烯基铬、钼或钨羰基物ＵＶ－Ｖｉｓ的研究李松兰，李桂萍，廖代正，吴琳，朱江真，宋礼成（南开大学化学系，天津，３０００７１）关键词紫外－可见光谱，浓度效应，计算机拟合本文研究了标题配合物［１，２］在５种溶剂中的紫外－可见光谱，发现ＣＴ带都存在λ...

制备方法对氧化石墨烯氧化程度及对Th(IV)、U(VI)吸附的影响

采用Hummers方法、优化Hummers方法及改进Hummers方法合成氧化石墨烯,并通过FT-IR、TGA、XRD、XPS、SEM以及元素分析等手段对制备产物进行了表征。结果表明,利用优化Hummers方法制备得到的氧化石墨烯具有较高的氧化程度。三种产物对Th(IV)、U(VI)的等温吸附实验结果表明,采用优化Hummers方法制备的氧化石墨烯对Th(IV)的最大吸附量为192.3 mg/g,相比于Hummers方法制备产物的吸附能力提高了38.5%;对U(VI)的最大吸附量为156.2 mg/g,吸附能力提高了28.1%,三种样品对Th(IV)、U(VI)的吸附都更加符合Langmuir等温吸附模型。此外,考察了优化Hummers方法制备的氧化石墨烯吸附Th(IV)、U(VI)的动力学和热力学参数,证实氧化石墨烯吸附Th(IV)、U(VI)符合准二级动力学方程,是自发吸热行为。

Aspergillus tubingensis介导植酸盐水解促进U(VI)-PO_4^(3-)生物矿化

从广东某铀尾矿库水下沉积物中分离筛选出了一株能水解植酸盐的真菌M5-1,对其菌落形态、ITS序列、最适生长pH值、对铀的耐受性及其水解植酸盐的效果进行了分析,随后对M5-1生物矿化铀过程中pH值、正磷酸盐浓度、铀浓度、铀去除率的变化进行了监测,对矿化产物的主要元素和矿物组成进行了分析.证实了真菌M5-1为Aspergillustubingensis(MH978623),其最适生长pH值范围为6～7,对铀(～0.84mmol/L)具有较强的耐受性;Aspergillus tubingensis介导植酸盐水解促进U(Ⅵ)-PO_4^(3-)矿化62d后,铀的去除率达95.2%;Aspergillus tubingensis介导U(Ⅵ)-PO_4^(3-)矿化过程中可能形成了难溶的氢铀云母和变钠铀云母矿物.结果表明,Aspergillustubingensis能有效水解植酸盐释放可溶性正磷酸盐,从而促进U(Ⅵ)-PO_4^(3-)矿化.研究结果为采用Aspergillus tubingensis介导植酸盐水解原位修复铀污染地表水提供了试验依据.

改性伊利石对水中放射性U(VI)的吸附性能研究

采用γ-氨丙基三乙氧基硅烷(KH550)对黏土矿物伊利石(Illite)进行改性,制备了吸附材料KH550@Illite。运用扫描电子显微镜、X射线衍射仪、傅里叶变换红外光谱仪等手段对其进行了表征,并考察了对模拟废水中U(VI)的吸附性能。结果表明:KH550已成功嫁接在伊利石表面,KH550对伊利石的改性为表面修饰作用。在溶液pH为5.0、初始U(VI)的质量浓度为5 mg/L、KH550@Illite投加量为8 g/L的优化条件下,反应60 min后达到吸附平衡,反应结束后U(VI)去除率达到99.25%,废水残余U(VI)的质量浓度为0.023 mg/L,能达到GB 23727-2009中规定的废水铀含量排放标准(≤0.05 mg/L)。吸附U(VI)符合准2级动力学方程,吸附过程为化学吸附,Langmuir吸附等温模型能更好地拟合KH550改性伊利石对水中U(VI)的吸附,主要以单分子层吸附。

灭活与非灭活条件下植物乳杆菌去除U(VI)的机理

在不同时间,pH值和生物量浓度条件下,进行了灭活与非灭活植物乳杆菌去除水中铀的对比试验,探讨了二者去除水中铀的机理,通过SEM-EDS、FTIR、XPS及XRD分析了铀与菌体表面的微观作用机理以及菌体表面沉积物的特征.结果表明:植物乳杆菌经灭活后,其吸附铀的能力得到显著的提高,当U(VI)初始浓度为10mg/L、pH值为6.0、37℃条件下,120min内灭活菌体对U(VI)的去除率为94.7%,而活菌体的去除率为88.9%.灭活菌体具有更高的铀吸附容量,在生物量浓度为0.06~0.24mg/L,pH值(3.0~7.0)条件下,灭活菌体与活菌体的U(VI)累积容量比W均大于1.SEM-EDS、FTIR分析结果表明,活细胞和灭活细胞都可通过细胞表面的羟基、酰基及羧基等官能团吸附、配位络合U(VI).XRD分析表明,活菌体可生物磷酸矿化水中的U(VI).活菌体的XRD谱图在2θ(18.023,25.492,27.343,40.813°处)有4个明显的磷酸铀酰晶体峰,而灭活菌体的XRD谱图显示为非晶态.XPS结果表明,活菌体可生物还原U(VI).活菌体能谱图中U4f7/2和U4f5/2轨道出现了结合能为380.20eV和390.65eV的U(VI)分裂峰,而灭活菌体的能谱图中没有出现U(IV)的分裂峰.

植物乳杆菌吸附水中U(VI)的特性与机理研究

以热灭活的植物乳杆菌为生物吸附剂,探讨了吸附U(VI)的影响,并采用扫描电镜-能谱、红外光谱等手段研究了U(VI)的吸附机理。结果表明,植物乳杆菌对U(VI)具有良好的吸附效果。在pH为6.0,温度30℃,灭活乳杆菌投加量为120 mg/L,初始U(VI)的质量浓度为10 mg/L时,植物乳杆菌对U(VI)的去除率可达94.28%,吸附平衡时间为4 h。吸附过程较好符合准2级动力学吸附模型和Freundlich模型。经过灭活的植物乳杆菌的菌体比表面积增加,能更好的吸附U(VI),配位络合是菌体吸附U(VI)的主要机理,参与吸附的官能团有细胞表面多糖与蛋白质羟基、蛋白质酰胺基、羧基与磷酸酯基等。此外菌体表面的静电作用也是吸附的方式之一。

绿泥石对U(VI)的吸附特征研究

以绿泥石为研究对象,利用静态吸附的方法,探究了吸附时间、U(VI)初始浓度、固液比、pH值、离子类型等对U(VI)吸附效果的影响.并讨论了U(VI)在绿泥石上的吸附动力学行为.结果表明:准二级动力学模型可以用来描述U(VI)在绿泥石上的吸附;绿泥石对U(VI)的吸附20 h即趋于稳定;最佳吸附固液附比为1∶150;最佳吸附初始浓度为20μg·mL^(-1);当pH为7时,吸附效果最好.过酸或过碱都会影响绿泥石对U(VI)的吸附;溶液中Ca^(2+)、HCO_3^-、CO_3^(2-)、SO_4^(2-)、Mg^(2+)对U(VI)的吸附有较强的抑制作用.

多光谱法研究钙黄绿素-U(VI)配合物与鲱鱼精DNA的作用机理

结合UV-Vis吸收光谱、荧光光谱和黏度测试法,系统研究了Tris-HCl(pH=7.25)缓冲溶液中U(VI)-钙黄绿素(CA)配合物与鲱鱼精DNA(hsDNA)的相互作用机理。通过摩尔比率法确定U(VI)-CA-hsDNA体系的结合比n_(U(VI))∶n_(CA)∶n_(hsDNA)=1∶2∶1。以双倒数法计算出此体系在不同反应温度下的结合常数,热力学计算表明U(VI)-CA-hsDNA的反应是疏水力驱动进行的自发行为。结合荧光分析、Scatchard法分析和溶液黏度变化分析,证明U(VI)-CA配合物对hsDNA的荧光猝灭为动态和静态混合猝灭过程,作用方式为嵌插和非嵌插的混合结合模式。实验表明U(VI)-CA配合物严重影响hsDNA的生物功能。