溶剂热处理对ZnS和CdS超细粉末结构形貌的影响

采用均相沉淀法制备单分散的ZnS和CdS纳米微粒,考察了溶剂热处理对CdS和ZnS粉末结构形貌的影响。结果表明:采用溶剂热处理,粉末形状呈现负离子配位多面体生长特征,闪锌矿型ZnS粉末由球形变为双锥状或四面体状,颗粒上有明显的电子衍射花纹;闪锌矿型CdS晶体粉末主要呈四面体形状,而纤锌矿型CdS晶体粉末则以锥状为主,并且粉末的晶型随溶剂热处理温度的升高和时间的延长更趋于完整。该工艺能同时进行脱水、除杂和晶化,具有防止氧化、有机试剂易于回收和能工业化等优点。

纳米ZnS、CdS水热合成及其表征

纳米ＺｎＳ、ＣｄＳ水热合成及其表征苏宜，谢毅，陈乾旺，钱逸泰（中国科学技术大学应用化学系合肥２３００２６）关键词硫化锌，硫化镉，水热技术ⅡＢ～ⅥＡ族化合物是主要的半导体发光材料，广泛应用于各种发光与显示装置［１］可采用气相反应、固气相反应及液相反应等...

Luminescence properties of ZnS:Cu, Eu semiconductor nanocrystals synthesized by a hydrothermal process

ZnS：Cu, Eu nanocrystals with an average diameter of 80 nm are synthesized using a hydrothermal approach at 200 ℃. The photoluminescence （PL） properties of the ZnS：Cu, Eu nanocrystals before and after annealing, as well as the doping form of Eu, are studied. The as-synthesized samples are characterized by X-ray diffraction, scanning electron microscopy, inductively coupled plasma-atomic emission spectrometry, and the excitation and emission spectra （PL）. The results show that both Cu and Eu are indeed incorporated into the ZnS matrix. Compared with the PL spectrum of the Cu mono-doped sample, the PL emission intensity of the Cu and Eu-codoped sample increases and a peak appears at 516 nm, indicating that Eu3＋ ions, which act as an impurity compensator and activator, are incorporated into the ZnS matrix, forming a donor level. Compared with the unannealed sample, the annealed one has an increased PL emission intensity and the peak position has a blue shift of 56 nm from 516 nm to 460 nm, which means that Eu3＋ ions reduce to Eu2＋ ions, thereby leading to the appearance of Eu2＋ characteristic emission and generating effective host-to-Eu2＋ energy transfer. The results indicate the potential applications of ZnS：Cu, Eu nanoparticles in optoelectronic devices.

三维乒乓菊状CdS/BiOBr催化剂的制备及其光催化降解罗丹明B

为提升BiOBr的光催化性能,通过两步法合成了三维乒乓菊状CdS/BiOBr催化剂。首先利用溶剂热法制备了BiOBr纳米片,接着采用水热法直接在层状BiOBr表面生长CdS粒子制备了CdS/BiOBr催化剂,并通过调整CdS与BiOBr的量比来调控催化剂的形貌。对制备的CdS/BiOBr催化剂的结构、形貌、光学性能等进行了表征分析,考察了其在可见光下对罗丹明B(RhB)的降解效果和稳定性,通过活性物种捕获实验和电子自旋共振测试分析确定了降解过程中的主要活性物质。结果表明:当CdS与BiOBr的量比为1∶3时,二者发生规则组合,形成独特的三维乒乓菊状层级结构;该催化剂有优异的光催化性能和稳定性,在可见光照射下120 min降解了99.5%的RhB,一级动力学常数为0.044 min^(-1),是纯BiOBr的3.67倍,经过7次光催化循环后仍保留了90.1%的催化活性;·O_(2)^(-)和h^(+)在RhB降解过程中发挥了主要作用,结合CdS和BiOBr的带隙结构提出了一种可能的光催化降解途径。

ZnS、CdS微-纳米材料的合成及其光学性质研究

采用硫代乙酰胺为均相沉淀试剂,通过水热法合成了结晶性好的ZnS微米球和CdS纳米材料,对其生长机理进行了探讨,产物通过XRD,SEM,UV-Vis,PL光谱对材料进行表征,结果表明类似条件下合成的ZnS微米球是由多个纳米粒子堆积而成,球与球之间分散性很好,而CdS纳米球粒径比ZnS小一些,分散性也相对较差.与粉末状样品相比,ZnS,CdS的UV-vis吸收峰分别出现了明显的蓝移.

水热法合成ZnS∶Au,Cu超细X射线发光粉

报道了水热法合成的高强度ZnS∶Au,Cu超细X射线发光粉及其光致发光(PL)和X射线激发发光(XEL)的光谱特性。200℃水热处理12h直接合成样品的纳米晶粒约15nm,尺寸分布窄,分散性好,具有纯立方相的类球形结构。氩气保护下1000℃焙烧1h后的样品存在一定的团聚,但团聚后尺寸为1～2μm,为超细X射线发光粉,此时样品为纯六角相的类球形为主的结构。所有样品的PL和XEL光谱均为宽带谱,水热法直接合成样品的XEL强度最强时,样品的Cu/Zn,Au/Cu比值分别为3×10-5和2。在此比值条件下,1000℃焙烧1h样品的XEL发光最强,此时其2个峰值分别位于445和513nm,且与未焙烧前相比强度增强了10倍左右。另外通过比较PL光谱与XEL光谱特性,讨论了PL和XEL光谱的发光机理和其不同的激发机制。

溶剂热法水热后处理合成ZnS纳米棒(英文)

采用水热后处理方法将片状、共价键结合的有机-无机复合硫化物ZnS.0.5en放入热液中热解,制备六方纤锌矿结构ZnS纳米棒,利用X射线衍射仪、透射电子显微镜、红外吸收光谱仪分析了水热后处理对ZnS的晶体生长和结构形貌的影响。结果表明:ZnS纳米棒是单晶结构,长度达1μm,直径约有30～40nm。纳米ZnS纳米棒的生长符合溶剂配位分子模板机理。

CdS/Zn-Fe LDO复合材料光催化降解孔雀石绿

采用沉淀法将CdS与锌铁层状双金属氢氧化物(Zn-Fe LDH)复合,高温煅烧后得到CdS/ZnO-ZnFe2O4复合材料(CdS/Zn-Fe LDO)。利用XRD、SEM、UV-Vis DRS及PL对复合材料的结构、形貌、光学性能进行了表征,研究了该复合材料在可见光下对孔雀石绿的光降解。结果表明,CdS/Zn-Fe LDO复合材料对孔雀石绿的光催化降解能力高于CdS或Zn-Fe LDO。其中,m(CdS)∶m(Zn-Fe LDH)=1∶1配比制备的CdS/Zn-Fe LDO(1∶1)光催化活性最大。光照20 min,20 mg CdS/Zn-Fe LDO(1∶1)对20 mg/L孔雀石绿的光降解率为96.6%。此外,该复合材料还可降解罗丹明B、亚甲基蓝、甲基橙、结晶紫等染料且光降解反应符合一级反应动力学。

碱化辅助水热法制备高活性CdZnS可见光催化剂

利用碱化辅助水热法制备Cd Zn S固溶体可见光催化剂CZS-r[r=n(Na OH)/2n(Cd2++Zn2+)].采用X射线衍射仪(XRD)、场发射扫描电子显微镜(FESEM)、透射电子显微镜(TEM)、氮气吸附-脱附仪和紫外-可见漫反射光谱仪(UV-Vis DRS)等对材料的晶体结构、微观结构及带隙能量(Eg)进行了表征.结果表明,碱化辅助能有效减小晶体的粒径,提高颗粒的分散性,增大材料的比表面积,并使得材料的带隙宽度变大,最值得注意的是,晶体中堆叠层错结构具有的独特界面电位能有效分离光生电子和空穴,阻碍其复合,从而显著提高材料的可见光催化制氢活性.材料的可见光(λ≥420 nm)催化还原制氢实验结果表明,CZS-0.5的5 h平均产氢速率为2154μmol/(h·g),是CZS-0[72μmol/(h·g)]的29.92倍.

MS(M=Cd或Zn)纳米粒子负载TiO_2纳米线的制备及可见光催化性能

以具有层状结构的钛酸盐纳米线、CdCl2或ZnSO4及硫代乙酰胺为原料,采用两步水热合成法制备了高温稳定的六方相CdS或低温稳定的立方相ZnS纳米粒子负载的TiO2纳米线复合材料。首先,CdCl2或ZnSO4与钛酸盐纳米线在水热条件下进行离子交换制得含Cd2+或Zn2+的钛酸盐纳米线;然后,在硫代乙酰胺溶液中于160℃下直接处理含Cd2+或Zn2+的钛酸盐纳米线就可获得负载有硫化物纳米粒子的TiO2复合纳米线。它们在酸浸后,TiO2纳米线的表面仍存在少量硫化物纳米粒子。通过测试酸浸后样品、纯TiO2纳米线和商用P25对亚甲基蓝水溶液的可见光催化降解实验结果证实,含CdS纳米粒子样品的光催化活性最高。

FCC汽油馏分在水热处理Zn/HZSM-5催化剂上的芳构化反应

制备了300 ℃、350 ℃、400 ℃和500 ℃不同水热处理温度下的Zn/HZSM-5催化剂,并用于FCC汽油馏分的芳构化反应.考察了水热处理温度对芳构化反应性能的影响,并与吡啶吸附红外光谱(FT-IR)相关联,研究了水热处理温度对催化剂表面酸性的影响.结果表明,水热处理Zn/HZSM-5的芳构化活性稳定性得以改善, 与未经水热处理的催化剂相比,400 ℃水热处理的Zn(2%)/HZSM-5催化剂芳构化反应36 h时,芳烃质量分数仍高达74.25%.随着水热处理温度的升高, B酸酸中心数在300～400 ℃变化不大,500 ℃显著减少,L酸酸中心数升高,400 ℃达到最大值后呈降低趋势,烯烃转化率、烷烃转化率和产品芳烃含量升高,水热处理400 ℃时均达到最大值,分别为83.62%、95.44%和92.23%,表明此时B酸中心和L酸中心比例协调性最佳.

天然斜发沸石水热转化Na-P沸石及其吸附镉的性能研究

以河北承德围场地区天然沸石为原料,对其进行水热改性制备Na-P沸石。采用X射线衍射仪、X射线光电子能谱仪、气体吸附仪、扫描电镜和能谱分析仪等对材料进行表征分析,采用Cd^(2+)离子评价材料的重金属离子去除性能。研究碱处理浓度、水热温度和时间对天然沸石结构的影响规律,着重研究所制备Na-P沸石的组成结构特征及重金属离子去除性能。结果表明:在NaOH浓度3 mol/L、水热温度100℃、水热时间12 h的条件下,斜发沸石可转化为纯度较高的Na-P沸石。所得材料对Cd^(2+)的吸附容量为35.7 mg/g,较天然沸石提升7倍。Na-P沸石性能的提升主要归功于其较低的硅铝比和较高的表面Na^(+)含量。

反应前驱物对制备硫化镉纳米粉的影响

本文给出了用水热技术制备ＣｄＳ纳米粉的方法，并研究了采用不同的反应前驱物对产物粒度、形状的影响。ＸＲＤ图谱和电镜照片表明在不同反应前驱物的作用下。

水热预处理对铝合金表面ZnAl-LDHs涂层防腐蚀性能的影响

目的提高表面ZnAl-LDHs涂层对铝合金的防腐蚀保护性能。方法首先将6061铝合金放入水热反应釜中,加入去离子水,在120℃温度下水热反应30 min。将经过水热预处理的铝合金分别放入50、80℃的0.005 mol/L的Zn(NO3)2溶液中浸泡4 h,在铝合金表面制备出ZnAl-LDHs涂层。利用XRD、SEM、EDS、EIS和极化曲线等技术,分析不同制备条件下,铝合金表面ZnAl-LDHs层的形貌、结构及其对铝合金的防腐蚀保护性能。结果水热预处理后,铝合金表面形成Al(OH)3和AlO(OH)混合层,在其上生长形成的ZnAl-LDHs涂层具有较优的层状结构、较高的结晶度和更加细小致密的纳米片。电化学阻抗和极化曲线的测试结果表明,表面ZnAl-LDHs层可以降低6061铝合金的腐蚀电流密度,提高腐蚀电位和电化学阻抗。水热预处理后的铝合金在80℃溶液中形成的ZnAl-LDHs层,其自腐蚀电流密度(J(corr))仅有0.018μA/cm^2,比未水热处理的铝合金上获得的ZnAl-LDHs层(0.101μA/cm^2)更低,在50℃溶液中形成的ZnAl-LDHs层也观察到相同的现象。结论通过水热预处理可在6061铝合金表面形成Al(OH)3和AlO(OH)混合层,将其作为ZnAl-LDHs层原位生长的前驱体,可以促进ZnAl-LDHs的结晶形核,提高其形核率,使ZnAl-LDHs层的纳米片更细小致密,从而使ZnAl-LDHs层对铝合金具有更好的防腐蚀保护性能。

Cadmium isotopic constraints on metal sources in the Huize Zn–Pb deposit, SW China

The Sichuan–Yunnan–Guizhou(SYG)Zn–Pb metallogenic zone in SW China contains>400 carbonatehosted hydrothermal Zn–Pb deposits.Some of these,such as the Huize,Tianbaoshan,and Daliangzi deposits,are super-large deposits with significant reserves of Cd,Ge,and Ag.However,the sources of these metals remain controversial.This study investigated the Cd isotopic geochemistry of the Huize deposit,the largest Zn–Pb deposit in the SYG area.Sphalerites formed at three stages in the deposit have different colors:black or dark brown(Stage I),red(Stage II),and light-yellow(Stage III).The d^(114/110)Cd values of the sphalerites are in the order Stage III<Stage I<Stage II.Kinetic isotopic fractionation is likely the key factor causing the lower δ^(114/110)Cd values in the early formed Stage I sphalerites than in laterformed Stage II sphalerites,with cooling of ore-forming fluids being responsible for the still lower values of the Stage III sphalerites.In galena,the δ^(114/110)Cd values are inversely correlated with Cd contents and tend to be higher in high-Zn galena.We speculate that Cd isotopic fractionation was significant during the precipitation of sphalerite and galena,with light Cd isotopes being enriched in galena rather than sphalerite.Comparison of the Cd isotopic signatures and Zn/Cd ratios of different endmembers suggests that the δ^(114/110)Cd values and Zn/Cd ratios of sphalerite from the Huize deposit,as well as other largescale deposits from the SYG area,are lie in those range of Emeishan basalts and sedimentary rocks and the mean δ^(114/110)Cd values of these deposits show good negative correlation with 1/Cd,suggesting that the ore-forming materials of these deposits were derived from the mixing of Emeishan basalts and sedimentary rocks.This study demonstrates that Cd isotopes can be useful proxies in elucidating ore genesis in large Zn–Pb deposits.

Synthesis and characterization of zeolite X obtained from kaolin for adsorption of Zn(Ⅱ)

This study deals with the synthesis and characterization of low-silica zeolite X, from calcined Kalabsha kaolin, for adsorption of Zn(Ⅱ) ions from aqueous solution. The synthesis processes is performed under hydrother-mal treatment in alkaline solutions. The obtained zeolite samples are characterized using X-ray diffraction, grain size distribution, surface area, and SEM. The critical molar ratios of both SiO2/Al2O3 and K2O/Na2O are about 2.9 and 0.16, respectively. Those ratios are needed to give individual low silica zeolite X in a minimum reaction time. The adsorption capacity of the synthesized products is determined by adsorption of Zn(Ⅱ) ions from solution. The results suggest that the zeolite obtained could be converted to a beneficial product, which will be used in future as an ion exchanger in removing heavy metals from wastewaters.

原子吸收分光光度法测定肉类样品中微量的铜铅锌镉

采用原子吸收法对肉类样品微量铜铅锌镉进行测定，重点对样品的前处理进行实验，拟订测试操作规程和仪器测量最佳条件，实验证明本法操作简便，准确快速，结果满意。

Infrared Emissivity Study on Semiconductor Pigment of Cd-Zn-S

Semiconductor pigment of Cd-Zn-S is synthesized through the solid state reaction method and its structure and surface morphology is characterized by X-ray diffraction (XRD) and scanning electron microscope(SEM). It is demonstrated that the crystal lattice of the product is hexagonal. When the heat treatment temperature increases, the distortion of crystal lattice reduces. The samples annealed at different temperatures agglomerate to different degrees while the one annealed at higher temperature agglomerates clearly. The infrared emissivity of Cd-Zn-S at two window-bands of 3-5 μm and 8-14 μm is researched. The researched result shows that the infrared emissivity of Cd-Zn-S in 8-14 μm wave bands is much higher than that in 3-5 μm wave bands. The infrared emissivity decreases with the increasing of heat treatment temperature, which reason is that with the increasing of temperature, the infrared absorption decreases and the scatter by the particles rises.

水热处理Zn/HZSM-5催化剂对丙烷芳构化反应的影响

考察了水热处理对 Zn/ HZSM- 5催化剂丙烷芳构化反应的影响 ;并采用 FT- IR手段 ,研究了处理温度对催化剂表面酸性的影响 .结果表明 ,随着水热处理温度的升高 ,单位晶胞中的 B酸中心数减少 ,而 L酸中心数增加 ,丙烷的转化率和芳烃选择性升高 ,水热处理温度为 40 0℃时达到最大值 ,此时催化剂的脱氢中心 Zn2 + 与聚合、环化的 B酸中心为最佳匹配状态 .随着处理温度的进一步升高 ,B酸中心数显著下降 ,丙烷的转化率和芳烃选择性下降 .

酿酒酵母吸附Zn^(2+)和Cd^(2+)的动力学

为了去除废水中的重金属离子,研究用酿酒酵母吸附金属离子Zn2+和Cd2+的生物吸附动力学。实验结果表明,当Zn2+和Cd2+初始浓度为1 mmol/L时,Zn2+和Cd2+在酿酒酵母上的吸附过程进行得很快,在3 h内即可达到吸附平衡。用准二级动力学方程式描述Zn2+和Cd2+在酿酒酵母上的吸附动力学行为(R2>0.99)。经计算得出,酿酒酵母吸附Zn2+和Cd2+的动力学参数k2分别为48 mg/(mg.min)和19mg/(mg.min),平衡吸附量qe分别为6.974 mg/g和12.77mg/g。酿酒酵母废菌体可用于处理低浓度含Cu2+和Cd2+的废水。