β-环糊精调控水溶液中Cu~(2+)的辐射还原

在β-环糊精(β-CD)水溶液的安全吸收剂量范围内,利用β-CD来调控Cu2+的辐射还原.随着β-CD的加入,硝酸铜的辐射还原产物从Cu2O逐渐转变为Cu.当β-CD浓度增大至8.0mmol·L-1时,辐射还原产物主要为Cu纳米粒子.在辐照过程中,Cu2+的还原没有经历Cu2O的中间过程.这是由于β-CD对·OH的清除减少了·OH与水化电子(ea-q)的反应,增大了ea-q的产额,从而有利于Cu的生成.另外,β-CD通过羟基在Cu纳米粒子表面的吸附可增强Cu纳米粒子在水溶液中的稳定性.用紫外-可见(UV-Vis)吸收光谱、粉末X射线衍射(XRD)和选区电子衍射(SAED)对Cu2+辐射还原产物进行了表征.     

AOT微乳液中通过水化电子产额调控合成BaSO_4纳米纤维

通过γ-辐照含有K2S2O8和BaCl2的二(2-乙基己基)琥珀酸酯磺酸钠(AOT)反相微乳液,将S2O82-通过辐射还原实现了SO42-的原位缓释,从而成功制备出BaSO4纳米纤维单晶,并进一步制得多层次的纳米纤维束结构.在此基础上,通过改变水与表面活性剂物质的量之比(ω值)、改变钡盐阴离子和在微乳液连续相添加芳香化合物等手段来调节水化电子(e-aq)产额,控制微乳液水池中S2O82-的还原和SO42-的缓释速率,成功实现了对BaSO4纳米粒子形貌的调控:随着ω值的增加或剂量率的增加,e-aq产额增加,从而加快了SO42-的释放,不利于BaSO4纳米纤维的生成;采用Ba(NO3)2为钡源时,NO3-能有效地降低e-aq产额和S2O82-的还原速率,因而在较高的剂量率和较高ω值下能得到BaSO4纳米纤维;在微乳液油相中加入甲苯来捕获油相中过量电子(e-oil),降低e-aq产额,从而在较高的剂量率下得到BaSO4纳米纤维.研究结果表明:通过e-aq产额调控纳米粒子形貌的机理在BaSO4纳米粒子的制备中得到很好体现.     

离子液体中铜纳米粒子膜的电沉积制备及表面增强拉曼光谱

采用恒电位方法研究了室温离子液体1-丁基-3-甲基咪唑氟硼酸盐([BMIM]BF₄)中氧化铟锡(ITO)电极表面Cu的沉积过程. 结果表明, Cu²⁺在ITO表面经中间产物Cu⁺还原为Cu. 采用XRD和SEM对不同电位下沉积层的组成和结构进行了考察. 结果表明, 表面组成和结构与沉积电位有关. 在较正电位下沉积所得为Cu/Cu₂O的混合纳米粒子; 在较负电位下为Cu纳米粒子. 随着沉积电位逐渐变负, 其形貌经历了花状、 棒状向球形纳米粒子转变的过程, 且所得沉积膜逐渐变得致密, 其中Cu纳米粒子膜表现出较强的表面增强拉曼散射(SERS)活性, 并且SERS信号均一.     

纳米Cu(OH)2分解温度对CuO粒度的影响

以CuSO4.5H2O和NaOH为原料,采用沉淀法制备得到Cu(OH)2纤维,再进行Cu(OH)2的分解反应.考察了在不同实验条件下温度对Cu(OH)2热分解过程的影响.结果表明:在反应温度20℃,反应终点pH值为12,搅拌速度为1 200 r.min-1,NaOH溶液的滴加速度为50 mL.min-1的反应条件下,得到的样品为纳米Cu(OH)2纤维,其直径为10~30 nm、长度为1~6μm;在固相纳米Cu(OH)2热分解制备CuO过程中CuO粒径随温度的升高而增大,在温度不超过200℃时CuO的粒径约为20 nm左右;在液相中先沉淀后升温时,产物的形貌为球形,CuO粒径随温度的升高而增大,低于80℃可得到纳米级的CuO.     

室温固相化学反应法合成Cd(OH)2纳米棒

在表面活性剂聚乙二醇(PEG)存在下,利用Cd(Ac)2·2H2O,CdCl2·2.5H2O,3CdSO4·8H2O和CdCO3分别与NaOH在室温下进行固相化学反应,合成了一系列的Cd(OH)2纳米棒,并利用XRD,TEM和SEM对其结构和形貌进行了表征.实验结果表明,表面活性剂PEG在Cd(OH)2纳米棒的形成过程中充当软模板,对产物形貌的控制起到决定作用.利用这种表面活性剂辅助的软模板固相化学反应法合成一维纳米材料,具有简便易行、反应条件温和以及能耗低等优点.     

PANI/Ce(OH)3-Pr2O3·3H2O/NanoG复合材料制备与表征

开发了反胶束模板-原位聚合纳米复合法制备聚苯胺(PANI)/Ce(OH)3-Pr2O3·3H2O/石墨纳米薄片(NanoG)纳米复合材料的方法.膨胀石墨在乙醇水溶液中经超声处理制得石墨纳米薄片,以苯胺的氯仿溶液为油相,稀土金属离子Pr3+、Ce3+水溶液为水相,依靠表面活性剂十六烷基三甲基溴化铵(CTAB)自组装形成的反胶束为模板-制备PANI/Ge(OH)3-Pr2O3·3H2O/NanoG复合材料.利用红外光谱(FTIR)、扫描电镜(SEM)、透射电镜(TEM)和 X-射线衍射(XRD)对该复合材料进行了表征和分析,研究了其导电性能和热性能.结果表明,PANI/Ce(OH)3-Pr2O3·3H2O/NanoG复合材料各相分散均匀,稀土纳米粒子在体系中以棒状的形态分布.热重分析表明,该复合材料的热稳定性明显提高;导电性研究说明,石墨纳米薄片的特殊的结构(较大的径厚比)对其在聚合物基体中形成导电网络具有重要作用;PANI/Pr2O3-Ce(OH)3/NanoG纳米复合材料的渗滤阀值低于1.0wt%.     

超微Ni(OH)_2纳米粒子的合成及其对Li~+的超高吸附性能（英文）

在葡萄糖水溶液中合成得到平均粒径为5 nm的α-Ni(OH)_2超微纳米粒子。研究结果发现,在水溶液中葡萄糖浓度能够控制α-Ni(OH)_2纳米粒子粒径的大小,我们对其中的原理进行了剖析。当没有葡萄糖存在时,合成得到的Ni(OH)_2晶型为β型,且颗粒粒径尺寸分布为微米级别。另外,研究发现α-Ni(OH)_2超微纳米粒子室温下对中性水溶液中Li~+具有较强的吸附性能,且这种吸附性能随粒径的减小而剧烈增大;粒径为5 nm的α-Ni(OH)_2粒子对Li~+的最大吸附量为214 mg·g~(-1)(远大于文献报道的有关吸附剂对Li~+的吸附容量),而粒径为1μm的β-Ni(OH)_2在相同条件下对Li~+的最大吸附量低于30 mg·g~(-1)。计算分析表明,Li~+在α-Ni(OH)_2纳米粒子表面吸附满足Freundlich方程,符合层层吸附模型。     

复合纳米材料Cu2O@Au对水体中罗丹明B的检测应用研究

制备了多面体Cu2 O纳米粒子,利用Cu2 O的还原性,在其表面原位生成了不同密度的Au纳米粒子,制备了Au、Cu共同增强拉曼信号的复合纳米粒子Cu2 O@Au.利用透射电镜(TEM)、扫描电镜(SEM)、X射线衍射(XRD)等对制备的Cu2 O和Cu2 O@Au的形貌、粒径、表面性能等进行了表征.研究了Cu2 O表面金纳米粒子的分布密度对水样中目标检测物罗丹明B的拉曼增强效果.结果表明,氯金酸浓度在1 mmol/L时制备的Cu2 O@Au表面均匀覆盖一层金纳米粒子,其表面增强拉曼效果最为显著,对水样中罗丹明B检测范围为1×10-2~5×10-6 mol/L.研究了此探针在PBS(1×)和酸性水溶液(0.01 mol/L HCl)中的稳定性,并将其用于沂河水样中靶标的检测实验,结果表明,其稳定性较好.     

醚化β-环糊精的制备及其混合膜对二甲苯异构体的选择性

采用WilliamSon合成法使氯化苄(PhCH2Cl)与β-环糊精(β-CD)进行醚化反应.红外光谱表明,所得产物为醚化β-CD.根据元素分析结果,计算出各反应的取代度和转化率.系统地考察了反应条件对转化率和取代度的影响.此外,考察了醚化β-CD与聚乙烯醇缩丁醛(PVB)共混膜对含10%对二甲苯的对/间二甲苯混合液的渗透气化性能的影响.结果显示,30℃时,共混膜的分离因子α可达1.16,而对二甲苯PX的渗透通量J高达70.57g/(m2·h).     

微波辐射对浆态床合成甲醇CuO/ZnO/Al2O3催化剂前驱体晶相转变的影响

在微波辐射条件下,对CuO/ZnO/Al2O3催化剂的沉淀母液进行老化,通过XRD、TG、H2-TPR,FTIR、HR-TEM和XPS对前驱体及催化剂微观结构的进行表征,探讨了CuO/ZnO/Al2O3催化剂前驱体晶相转变过程中微波辐射的作用。结果表明,微波辐射有利于Cu2+取代Zn5(CO3)2(OH)6中Zn2+的同晶取代反应。微波辐射的老化过程中,首先发生Cu2+取代Zn5(CO3)2(OH)6中Zn2+生成(Cu,Zn)5(CO3)2(OH)6的同晶取代反应,并于1.0 h内基本完成;随着老化时间继续延长,主要进行Zn2+取代Cu2(CO3)(OH)2中Cu2+生成(Cu,Zn)2(CO3)(OH)2的同晶取代反应,同时(Cu,Zn)5(CO3)2(OH)6进一步结晶。与常规老化1 h制备的前驱体相比,微波辐射老化1.0 h制备的前驱体含有较多的(Cu,Zn)5(CO3)2(OH)6物相,有助于增强焙烧后CuO/ZnO/Al2O3催化剂中CuO-ZnO协同作用,提高表面铜含量,进而提高CuO/ZnO/Al2O3催化剂在浆态床合成甲醇的催化活性和稳定性,在400 h浆态床合成甲醇评价期间,甲醇时空收率最大达318.9 g.kg-1.h-1,失活率仅为0.11%.d-1。     

多元醇法制备Cu2O/CNTs复合材料的研究

以Cu(CH₃COO)₂•H₂O和经硝酸处理的CNTs作为原料, 采用多元醇法成功合成了纳米氧化亚铜均布于碳纳米管表面的复合光催化剂. 用透射电镜(TEM), 高分辨透射电镜(HRTEM), X射线粉末衍射(XRD)对样品进行了表征, 测试结果表明大小为2～5 nm的氧化亚铜纳米颗粒均匀分散于碳纳米管的表面. 讨论了反应条件对Cu₂O在CNTs上负载效果的影响并就多元醇法合成Cu₂O/CNTs复合材料的反应机理作了初步探讨.     

NaOH浓度对Cu_2O结构及甲醛乙炔化性能的影响

以CuCl_2·2H_2O为铜源,NaOH为沉淀剂,L-抗坏血酸钠为还原剂,采用液相还原法制备了Cu_2O,并将其应用于甲醛乙炔化反应制1,4-丁炔二醇.借助傅里叶变换红外光谱(FT-IR)、拉曼光谱(Raman)、X射线粉末衍射(XRD)、X射线光电子能谱(XPS)、扫描电子显微镜(SEM)和H_2程序升温还原(H2-TPR)等手段研究了NaOH浓度对Cu_2O结构、性质及催化性能的影响.结果表明,调变NaOH浓度改变了Cu2O的结晶度与粒径,从而使Cu_2O表现出不同的炔化性能.低NaOH浓度时,Cu_2O结晶度低,粒径小,易被还原为非活性的金属Cu;高浓度时,Cu_2O结晶度过高,粒径大,难以转化为活性物种炔化亚铜,两者均造成催化剂活性较低.而中等浓度的NaOH使Cu_2O具有了适宜的结晶度与粒径大小,Cu_2O可高效转化为炔化亚铜活性物种,表现出最优的炔化性能.     

使用变温原位X射线衍射技术认识氧化铜在氢气和一氧化碳气氛下的物相变化*

实验与理论相结合是化学专业教与学的原则。通过运用原位X射线衍射技术(in-situ XRD)探究氧化铜在氢气和一氧化碳气氛下的还原,结果发现无论在氢气或一氧化碳气氛下,从300 ℃开始,氧化铜逐渐被还原为氧化亚铜和铜单质,且该3种物相同时存在。直至温度升至450~500 ℃时,所有的氧化铜和氧化亚铜全部变为了铜单质。实验结果表明氧化铜的还原并非是一个由CuO → Cu2O → Cu逐步还原的单一过程,理论上可以得到的纯氧化亚铜物相在实验过程中并未得到,对此结果进行了分析。另外,将大型仪器尤其是原位表征技术推广到本科教学中具有重要意义。     

1-辛基-3-甲基咪唑功能化石墨片负载氧化亚铜催化二氧化碳电还原制乙烯

电催化还原二氧化碳制备乙烯是备受关注的热点问题,高效催化剂的制备是决定乙烯产率的关键因素。本文在1-辛基-3-甲基咪唑氯的水溶液(OmimCl : H₂O = 1 : 5,体积比)中通过电剥离石墨棒制备了1-辛基-3-甲基咪唑功能化石墨片(ILGS),在水溶液中负载氧化亚铜后得到氧化亚铜/1-辛基-3-甲基咪唑功能化石墨片复合材料(Cu₂O/ILGS),通过透射电镜、X射线光电子能谱、拉曼光谱和X射线衍射对其组成和结构进行了系统研究,发现ILGS由多层石墨烯组成,表面富含缺陷。这些缺陷被1-辛基-3-甲基咪唑通过共价键修饰,形成类似鸟巢状的微结构,平均直径5 nm的Cu₂O纳米颗粒在石墨片表面均匀分散。在0.1 mol∙L⁻¹碳酸氢钾水溶液中,研究了Cu₂O/ILGS在不同电压下催化CO₂电还原的性能。结果表明,Cu₂O是主要活性中心并在CO₂还原过程中被逐渐还原成铜,导致产物的法拉第效率随着反应时间而变,在−1.3 V (vs RHE)电压下,乙烯的法拉第效率最高达到14.8%,其性能归因于Cu₂O/ILGS复合材料中的鸟巢状微结构对Cu₂O纳米颗粒的稳定作用。     

The composite catalysts of Cu/CuxO nanoparticles supported on the carbon fibers were prepared for styrene oxidation reaction

In this paper a novel simple method for preparing two different catalysts with various‐valences copper was reported. Carbon nanofibers supported copper‐cuprous oxide nanoparticles (Cu‐Cu₂O NPs/CNFs) and copper oxide nanoparticles (CuO NPs/CNFs) through electrospinning, adsorption and reduction in the high‐pressure hydrogenation and the high‐temperature calcination methods. These catalysts were investigated by a series of characterizations and were applied in reaction in nitrogen atmosphere, which had a good catalytic activity and selectivity of benzaldehyde for the reaction. Above all, the new study has been certified clearly, in which Cu‐Cu₂O NPs/CNFs and CuO NPs/CNFs composite catalysts enhanced the generation of benzaldehydeand the excellent catalytic properties were exhibited.     

Conditions for the formation of copper nanoparticles by reduction of copper(II) ions with hydrazine hydrate solutions

Optimal conditions were found for the preparation of copper nanoparticles in aqueous solution via reduction of copper(II) ions with hydrazine hydrate. The effects of ligand environment of copper(II) in the initial solution (hydrate, ammonia, citrate, and glycine complexes), concentration, pH, surfactants, temperature, and mode of heating were examined. The obtained colloidal systems were studied by optical spectroscopy, X-ray photoelectron spectroscopy, X-ray powder diffraction, and atomic force microscopy. The examined colloids were found to contain generally spherical copper nanoparticles with a diameter of about 10 nm, which were coated with a copper(I) or copper(II) oxide and hydroxide film.     

Photo- and radiation-induced preparation of nanocrystalline copper and cuprous oxide catalysts

Spherical copper nanoparticles have been prepared by photo- or radiation-induced reduction of aqueous solutions containing 10⁻³ mol.dm⁻³ copper sulphate or formate, 1.3 mol.dm⁻³ propan-2-ol and polyvinyl alcohol as a stabilizer. Increase of initial copper concentration to 10⁻² mol.dm⁻³ resulted in formation of different reaction product—octahedral cuprous oxide nanoparticles. Solutions were irradiated by means of electron beam, ⁶⁰Co γ rays (dose rate 70 Gy.h⁻¹) or by 400 W medium-pressure mercury lamp and were characterised by UV-Vis spectrophotometry, X-Ray Powder Diffraction, TEM and SEM. Pink to violet colour of colloidal copper solutions corresponded to measured copper surface plasmon band at circa 580 nm and has been found to be very sensitive to oxygen, which causes dissolution of particles. Therefore, the influence of purging by nitrogen gas prior to irradiation was thoroughly examined and has been found to only hinder, not alter irradiation effects. Moreover, the evolution of absorption spectrum of colloidal copper solution in contact with air has been measured, revealing interesting non-monotonous dependence on the air exposure time, probably caused by formation of protective oxide layer. Catalytic activity of prepared cuprous oxide has been measured by catalytic decomposition of hydrogen peroxide and has been found to be higher or comparable to commercial cuprous oxide.     

Copper hydroxide nanoneedle and nanotube arrays fabricated by anodization of copper

Cu(OH)2 nanoneedle and nanotube arrays were electrochemically synthesized by anodization of a copper foil in an aqueous solution of KOH. The nanoneedles and nanotubes were constructed from nanosheets of Cu(OH)2. Controlling the electrochemical conditions can qualitatively modulate the lengths, amounts, and shapes of Cu(OH)2 nanostructures. The composition of as-prepared Cu(OH)2 nanostructures has been confirmed by X-ray diffraction and select-area electron diffraction. The influences of the KOH concentration of the aqueous electrolyte, the reaction temperature, and current density on the morphology of Cu(OH)2 nanostructures were investigated, and the formation mechanism of the nanostructures is discussed. Furthermore, Cu(OH)2 nanoneedles can be successfully transformed to CuO nanoneedles with little morphology change by heating. This work developed a simple, clean, and effective route for fabrication of large area Cu(OH)2 or CuO nanostructured films.     

Preconcentration of trace elements on oxine cellulose

Summary X-ray Diffraction Analysis of Corrosion Products on Electrochemically Polarized Copper Surface An investigation was undertaken to examine the feasibility of X-ray diffractometry for the identification and characterization of corrosion products formed, electrochemically, on copper surface in various aqueous media. The removal of the products from the metal surface was useful in overcoming serious interferences from the intense diffraction lines of copper and was most satisfactory for the identification of common film components such as cuprous oxide, cuprous chloride and cupric oxide. In addition, the results obtained for the surface film components by slow scan linear (or potentiodynamic) polarization agreed favourably with the X-ray diffraction analysis. The influence of the solution pH and temperature on the nature of the corrosion products was evident on the results obtained by both techniques. The dominance of cuprous oxide as the major film component at the low solution pH and of cupric oxide as the predominant species at the higher solution pH and higher temperature were also confirmed by both results.Work undertaken while at the School of Applied Chemistry, Western Australian Institute of Technology, W. A. 6102 (Australia).