海带吸附Ag(Ⅰ)的物理化学特性研究

以海带(Laminaria japonica)干粉为吸附剂,研究了海带吸附Ag+的物理化学特性.结果表明海带对Ag+有很强的吸附能力,最大理论吸附量可达273mg/g干重.该吸附在20～40℃范围内是一个不依赖于温度的快速过程;对溶液的pH值有较宽的适应范围;海带浓度在0.5～4.0mg/L范围内,海带对Ag+的吸附量与海带粉的浓度成反比;起始Ag+浓度在10～800mg/L的范围内,海带对Ag+的吸附量与起始Ag+浓度成正比.吸附等温线符合Langmuir模型.TEM观察结果表明,海带能够将Ag+还原成Ag0.海带可用于从含Ag+的强酸废液中回收Ag+,当废液中Ag+浓度为121.9mg/L时,其回收率可达98.3%.     

巨大芽孢杆菌D01吸附金(AU3+)的谱学表征

对休眠的巨大芽孢杆菌(Bacillus megatherium)D01菌体吸附Au^3 的作用过程进行了谱学表征．运用AAS考察了pH、时间和温度对D01菌体吸附Au^3 过程的化学动力学和热力学相关参数的影响．D01菌粉中硫元素含量的EDX分析说明该菌体中对Au^3 具有还原作用的L-半胱氨酸和蛋氨酸的含量极少；D01菌体水解后葡萄糖含量的UV-vis测定说明该菌体水解产物中含有一定量的还原糖，空白的和吸附Au^3 的D01菌体的FFIR检测表明该菌体细胞壁肽聚糖层糖类化合物的羟基和肽链侧链氨基酸残基离子化羧基为吸附Au^3 的活性基团；肽聚糖层部分多糖的水解产物低聚糖、二糖及单糖等还原糖的半缩醛羟基游离态醛基为电子供体，将Au^3 原位还原成Au^0．葡萄糖和Au^3 相互作用的XRD和FFIR表征证明Au^3 是在还原糖的醛基上直接被还原成Au^0．     

微生物还原制备高分散度负载型钯催化剂

用地衣形芽孢杆菌 ( Bacillus licheniformis) R0 8菌体还原、制备高分散度负载型钯催化剂。透射电镜观察表明 ,R0 8菌体能够吸附还原 Pd2 成 Pd0 颗粒。IR谱分析发现 ,细胞壁上的 - COO- 和 - HPO42 - 基团可能与菌体吸附 Pd2 的过程有关。XPS测定结果表明 ,在载体 γ- Al2 O3上的 Pd2 离子被 R0 8菌体还原成 Pd0。所形成的 Pd0 γ- Al2 O3催化剂经加热处理后 ,载体 γ- Al2 O3上的 Pd0 颗粒高度分散 ,其平均粒径为 5nm。该催化剂能够高效地催化一氧化碳的氧化反应。     

啤酒酵母废菌体吸附Pd2+的物理化学特性

以啤酒酿造厂的啤酒酵母废菌体为生物吸附剂,研究死的啤酒酵母菌体从PdCl₂溶液中吸附Pd²⁺的物理化学特性.结果表明,该菌体吸附Pd²⁺受吸附时间、溶液pH值、菌体浓度和Pd²⁺起始浓度等因素的影响.菌体吸附Pd²⁺是个快速的过程,吸附45min时吸附量达最大,但在最初的3min内,吸附量可达到最大吸附量的92%.在5～60℃范围内,吸附作用不受温度影响.吸附作用的最适pH值为3.5.在Pd²⁺起始质量浓度为30～300mg/L范围内和菌体质量浓度为2g/L的条件下,菌体对Pd²⁺的吸附作用符合Langmuir和Freundlich等温吸附模型.在pH=3.5,Pd²⁺与菌体质量比为0.2和30℃条件下吸附60min,吸附量达94.5mg/g.从废钯催化剂处理液回收钯,吸附量为32.2mg/g.XPS分析表明,该菌体能吸附水溶液中的Pd²⁺.TEM结果表明,在无外加电子供体时,死的啤酒酵母废菌体能够吸附和还原溶液中的Pd²⁺成Pd⁰微粒,Pd⁰微粒可进一步形成有一定形状的钯晶粒;该菌体还能使吸附在γ-Al₂O₃上的Pd²⁺还原成Pd⁰.     

厌氧条件下芽孢杆菌Bacillus sp.dwc-2对模拟地下水中U(Ⅵ)的吸附行为研究

本文在厌氧条件下,研究了西南地区土壤中一种典型微生物芽孢杆菌Bacillus sp.dwc-2对模拟地下水U(VI)的吸附行为,重点考察了时间、pH、NaHCO_3、温度、阴离子、腐殖酸以及富里酸对吸附的影响,并利用SEM、EDS、FT-IR和XRD对样品进行了表征。结果表明:在pH 7.0、[NaHCO_3]=5 mmol·L~(-1)和T=30 ℃条件下,芽孢杆菌对U(VI)有最大的吸附率。初始pH值升高及阴离子浓度增大会抑制芽孢杆菌对U(VI)的吸附;随着U(VI)初始浓度的增加,芽孢杆菌对U(VI)的吸附率呈先增加后降低的趋势;腐殖酸和富里酸则会抑制芽孢杆菌吸附U(VI)。吸附均在120 h达到平衡,吸附过程均符合准二级动力学模型,说明吸附以化学吸附为主。Langmuir和Freundlich模型拟合结果显示,芽孢杆菌吸附U(VI)为单分子层吸附。上述结果可为真实环境中微生物吸附U(VI)提供基础数据和参考。     

含硫、亚砜、砜基氨基吡啶螯合树脂对Ag(I)吸附选择性能及机理研究

以氯球为原料制备了PVBS-AP、PVBSO-AP和PVBSO2-AP等3种螯合树脂。用静态法研究了3种树脂对Ag+的吸附性能,并采用光电子能谱手段研究了其对Ag+的吸附机理。研究结果显示,吸附过程通过树脂中N、S原子参与配位完成的,且N原子的配位能力受溶液酸度影响较大;3种树脂均可用于Ag+-Ni2+,Ag+-Pb2+,Ag+-Zn2+等二元体系中Ag+的选择分离,且树脂的稳定性好。     

乳酸杆菌A09吸附还原Ag(I)的谱学表征

Pooley[1]发现氧化亚铁硫杆菌(Thiobacillus ferroxidans)和氧化硫硫杆菌(Thiobacillus thiooxidans)能在其细胞表面累积银,形成Ag2S,每克干重细胞吸附250 mg Ag2S.文献[2]也报导了类似的研究结果.一些霉菌也具有吸收金、银等重金属的能力[3].Brierley等[4]研究了用微生物制备回收贵金属的去除剂(MRA),用它能从摄影废液中回收银,每克MRA累积94 mg Ag;同时指出,贵金属生物吸附也包含金属离子被还原为金属的过程.     

黄孢原毛平革菌210对稀土离子的吸附作用研究

通过电感耦合等离子体发射光谱(ICP-OES)、扫描电镜等手段研究了黄孢原毛平革菌210对镧离子(La3+)及其他稀土离子的吸附能力。结果表明,在pH=7,La3+浓度为40 mg.L-1,菌体投加量60 mg.L-1(以干重计),吸附时间120 min时,黄孢原毛平革菌210的吸附量最大,达141.5±4.72 mg.g-1。经盐酸预处理的菌体吸附能力有所提高,其他预处理则使菌体吸附能力下降。解吸剂柠檬酸和EDTA都能较好地解吸La3+。黄孢原毛平革菌210对单一稀土离子的吸附能力差异较大。在15种混合稀土离子溶液中,对Lu3+,Sm3+,Eu3+的吸附量较高,对混合稀土离子具有一定的富集、分离作用。扫描电镜发现La3+可能主要以盐的形式沉积在菌体表面上。     

乳酸杆菌A09吸附还原Ag（Ⅰ）的谱学表征

Pooley[1]发现氧化亚铁硫杆菌(Thiobacillusferroxidans)和氧化硫硫杆菌(Thiobacillusthiooxidans)能在其细胞表面累积银,形成Ag2S,每克干重细胞吸附250mgAg2S.文献[2]也报导了类似的研究结果.一些霉菌也具有吸收金、银等重金属的能力[3].Brierley等[4]研究了用微生物制备回收贵金属的去除剂(MRA),用它能从摄影废液中回收银,每克MRA累积94mgAg;同时指出,贵金属生物吸附也包含金属离子被还原为金属的过程.在微生物吸附还原贵金属前期研究[5－9]的基础上,我们从金、银矿土等不同来源的细菌菌株中,筛选获得一株吸附、还原Ag＋…     

一步热解法制备Cu/Fe双金属生物炭复合材料及其高效吸附Pb2+性能

使用一步热解法制备了 Cu/Fe双金属生物炭复合材料(BC@Cu/Fe-X,X=3、5、10)和 Fe生物炭复合材料(BC@Fe)。考察了Cu掺杂量对BC@Cu/Fe-X吸附Pb²⁺的影响,确定最佳掺杂比例。结果显示BC@Cu/Fe-5吸附Pb²⁺性能最好。考察了吸附时间、Pb²⁺浓度、pH、背景离子、空气中老化等实验条件对 BC@Cu/Fe-5 吸附 Pb²⁺的影响。通过动力学、热力学数据拟合分析了BC@Cu/Fe-5吸附Pb²⁺的行为,利用X射线粉末衍射(XRD)、X射线光电子能谱(XPS)、傅里叶变换红外光谱(FTIR)等表征手段解析了BC@Cu/Fe-5吸附Pb²⁺前后特征峰变化。BC@Cu/Fe-5吸附Pb²⁺的机理如下：大约42%的Pb²⁺被还原为Pb⁰,33%的Pb²⁺形成PbO/Pb(OH)₂,25%的Pb²⁺与O—H、C—O、C=O、COO、Fe—O等官能团形成配合物。Cu掺杂可以提高Fe还原Pb²⁺的能力。     

A further insight into the mechanism of Ag+ biosorption by Lactobacillus sp. strain A09

The mechanism of Ag(+) biosorption by resting cell of Lactobacillus sp. strain A09 has been further investigated at the molecular level using spectroscopic techniques. The values of estimated equilibrium constants, rate constants, half-life periods and apparent enthalpies of the binding reaction were calculated via the determination of Ag(+) adsorbed by the biomass using atomic absorption spectrophotometry (AAS). The reductive ratio of the Ag(+) to Ag(0) by the A09 biomass was examined by X-ray photoelectron spectroscopy (XPS). Analysis for sulfur and nitrogen atomic contents in dry powder of the biomass with EA-1110 elemental analysis (EA) showed that amino acid residues retaining the reductive property of Ag(+) to Ag(0) are very small quantity, whereas glucose content in the hydrolysates of the biomass analyzed by ultraviolet-visible spectrophotometry (UV-vis) indicated that the amount of reducing sugars in the biomass is much larger than 2.71%. The fourier transform infrared (FTIR) spectrophotometry on blank and silver-loaded biomass demonstrated that the chemical functional group such as the free aldehyde group of the hemiacetalic hydroxyl group from reducing sugars, i.e. the hydrolysates of the polysaccharides from the cell wall plays a leading role in serving as the electron donor for reducing the Ag(+) to Ag(0). This result was further supported by characterizations on the interaction of the Ag(+) with glucose using X-ray powder diffractometry (XRD) and FTIR spectroscopy.     

Spectroscopic characterization of Au3+ biosorption by waste biomass of Saccharomyces cerevisiae

Some spectroscopic characteristics of Au3+ biosorption by waste biomass of Saccharomyces cerevisiae have been reported in this paper. The effect of temperature on the correlation parameters of chemical kinetics and thermodynamics of the binding reaction was investigated by using AAS. XRD diffraction pattern of gold-loaded biomass revealed that the Au3+ bound on the cell wall of the biomass had been reduced into gold particle. FTIR spectrophotometry on blank and gold-loaded biomass demonstrated that active groups such as the hydroxyl group of saccharides, and the carboxylate anion of amino-acid residues, from the peptidoglycan layer on the cell wall seem to be the sites for the Au3+ binding, and the free aldehyde group of the hemiacetalic hydroxyl group from reducing sugars, i.e. the hydrolysates of the polysaccharides on the peptidoglycan layer, serving as the electron donor, in situ reduced the Au3+ to Au0. XPS and IR characterizations of the interaction between glucose and Au3+ further supported that the reduction of Au3+ to Au0 can directly occur at the aldehyde group of the reducing sugars.     

TLC separation and derivative spectrophotometry of some amino acids

Chromatographic systems for the separation of amino acid mixtures on RP-18 as a stationary phase have been elaborated. The best results were obtained using methanol-water (1:1, v/v; 1:3, v/v; 1:5, v/v) as a mobile phase. The following amino acids have been examined: asparagine, arginine monohydrochloride, cystine, cysteine chloride, glycine, histidine monohydrochloride, hydroxyproline, isoleucine, leucine, lysine monochloride, methionine, ornithine monohydrochloride, phenylalanine, proline, threonine, tryptophan, tyrosine, serine, valine. Histidine (as monohydrochloride) and methionine were determined by first-, second- and third-derivative spectrophotometry in a mixture of several amino acids.     

Ag+/Ag/ZnO多孔纳米结构纤维材料的制备及可见光催化性能

借助棉花纤维模板, 采用两步法制备了Ag⁺/Ag/ZnO多孔纳米结构纤维材料, 并利用X射线衍射(XRD)、 X射线光电子能谱(XPS)、 扫描电子显微镜(SEM)和紫外-可见光谱(UV-Vis)等对其进行了表征. 以亚甲基蓝(MB)的脱色降解为模型反应, 考察了银修饰量(摩尔分数, 0~1.50%)对ZnO纳米结构纤维材料光催化性能的影响. 结果表明, 利用模板辅助的两步法制备了Ag⁺-Ag共修饰的ZnO多孔纳米结构纤维材料Ag⁺/Ag/ZnO, Ag⁺和Ag通过改变ZnO的晶胞结构、 光吸收特性及形貌等影响其光催化性能; 在可见光条件下, Ag⁺/Ag/ZnO的催化性能优于纯ZnO, 且与修饰量有关.     

Tea polyphenol-assisted green synthesis of Ag-nanodiamond hybrid and its catalytic activity towards 4-nitrophenol reduction

Herein, we describe an environmentally friendly strategy to synthesize Ag nanoparticles on Nanodiamond (ND) by utilizing natural adhering and reduction properties of tea polyphenols (TPs). Firstly, the surface of ND was modified by TPs through their natural adhering ability. Then, the modified TPs functioned as reducing agents for reducing Ag precursor in situ. The synthesis process, structure and its physicochemical properties of the nanohybrid were tracked and characterized by UV-Vis, FTIR, TGA, HRTEM, XRD and XPS. It has been shown that Ag nanoparticles with uniform size and distribution were anchored successfully on the surface of ND. The ND supported Ag nanoparticles displayed highly water dispersibility due to the hydrophilicity of TPs, as is very important in heterogeneous catalysis. The catalytic performance of this nanohybrid was evaluated comprehensively by catalyzing 4-nitrophenol reduction by sodium borohydride, which is often used as a model reaction, showing excellent catalytic activity and recycling stability.     

MMgF4(M=Ca,Sr, Ba)体系中Eu和Tb的电荷迁移

于不同气流中, 合成了MMgF4:xEu,yTb复合氟化物磷光体。该体系中Eu^3^+和Eu^2^+共存。Tb的存在影响Eu的价态存在形式。ESR测试表明, 随Tb的掺入浓度增加, Eu^2^+的浓度呈规律性变化。随Eu的掺入, 样品的XPS谱中出现了四价铽的Tb3d5/2特征伴峰。认为Eu^3^+和Tb^3^+之间存在电荷迁移平衡。即Eu^3^++Tb^3^+=Eu^2^++Tb^4^+。通过半定量手段研究了SrMgF4中这一衡的平衡常数。     

Selective synthesis of copper microsheets and ultralong microwires via a surfactant assisted hydrothermal process

The surfactant assisted hydrothermal process for selective preparation of copper nanosheets and ultralong microwires by reducing Cu²⁺ with 2-(bis-phosphonomethylamino)propionic acid (dpc) under the action of cetyltrimethylammonium bromide (CTAB) or polyvinyl pyrrolidine (PVP) is presented. X-ray powder diffraction (XRD) and energy dispersive X-ray analysis (EDX) indicate that the products are pure Cu of cubic phase. The effects of starting material concentration and reaction time on morphology of nanosheets have been studied by scanning electron microscopy (SEM). The presence of CTAB and PVP as capping agents is identified by EDX, transmission electron microscopy (TEM) and FT-IR. The possible growth process for ultralong microwires was studied by stopping the growth at a series of intermediate morphology stages based on SEM observations. Optical properties of Cu nanosheets and ultralong microwires were studied by UV-Vis spectrophotometry.     

一步火焰辅助热解法制备Fe掺杂嵌碳TiO2及其光催化性能

以钛酸四丁酯、无水乙醇和无水氯化铁为前驱体,通过一步火焰辅助热解法制备了Fe掺杂嵌碳TiO₂,并研究了样品的光催化活性. 利用扫描电子显微镜及能谱、X射线光电子能谱、X射线粉末衍射和紫外-可见漫反射吸收光谱等对样品的形貌、组分、晶型和光吸收进行了表征,并研究了样品在紫外和可见光下的光催化活性. 结果表明,无需后续热处理可直接得到主要是锐钛矿相TiO₂的样品,Fe³⁺以替位掺杂形式进入TiO₂晶格,随掺杂量增加,样品在可见光区域的吸光度提高,吸收带边红移. Fe掺杂量（摩尔分数）小于0.2%可改善样品的光催化活性,当Fe掺杂量为0.1%时,样品在可见光和紫外-可见光照射下均显示出最高的降解亚甲基蓝速率.     

铁氰化钆修饰电极的固态电化学及电催化性能

制备了一种新的稀土铁氰化物——铁氰化钆(GdHCF), 并对其进行了表征. 元素分析、EDX和TGA结果表明, GdHCF的计量式为NaGdFe(CN)6•12H2O(在NaCl溶液中制备), 红外光谱结果显示GdHCF晶体中有两种形式的水分子存在, 一种是靠氢键结合的填隙水分子(5个), 一种是与Gd配位的配位水分子(7个)；XPS结果表明GdHCF中铁为+2价, 钆为+3价. 将GdHCF固定到石墨(SG)电极上(GdHCF/SG), 研究了它的固态电化学性能, 其循环伏安曲线上表现出一对良好且稳定的氧化还原峰, 式量电位E0′几乎不随扫速而变化(在10~300 mV•s−1范围内, E0′平均值为(197±3) mV)；并且E0′与支持电解质中阳离子(Na+)活度的对数(lgaNa+)之间呈线性关系, 斜率为54.1 mV, 这一特性关系可用于测定NaCl溶液中Na+的活度. 进一步研究的结果表明, GdHCF对神经递质多巴胺(DA)和抗坏血酸(AA)的电化学氧化均具有催化作用, 催化电流随DA(或AA)浓度的增加而增加.