ZnS-CdS核壳纳米微晶的制备与光学特性

采用微乳液法制备了核壳结构ZnS/CdS纳米微晶.以XRD、TEM表征其结构、粒度和形貌,UV、PL表征其光学性能.制得的纳米微晶近似呈球形,粒径4～5nm.研究了不同CdS壳层厚度的ZnS/CdS纳米微晶的光学性能,PL谱表明壳层CdS的修饰可减少ZnS的表面缺陷,表面态发射和非辐射跃迁减少,带边直接复合发光的几率增大,发光效率大大提高;在壳层CdS达到一定厚度时,PL谱却表现为CdS的特征发射,同时发现核心ZnS对壳层CdS的发光具有增强作用,提出了ZnS/CdS发光机理的能带模型.     

微乳液法制备二氧化硅包覆ZnS:Mn/CdS纳米晶

采用微乳液法制备核壳结构ZnS:Mn/CdS(～4.5nm)纳米晶,为获得水溶性纳米晶,继续向此微乳液添加硅酸乙酯(TEOS),并使用氨水作为催化剂,通过TEOS水解缩聚反应,在ZnS:Mn/CdS粒子表面生长连续的二氧化硅壳层.采用透射电子显微镜(TEM)、X射线衍射(XRD)、红外光谱(IR)、光致发光谱(PL)对其表面形貌、结构和光学特性进行表征.ZnS:Mn /CdS纳米粒子表面被二氧化硅壳层完全包覆,粒径大小约为10nm左右,粒子均匀性好.由于二氧化硅相无定形且透光性良好,二氧化硅包覆ZnS:Mn/CdS纳米晶的光学特性与未包覆的ZnS:Mn/CdS极其相似.     

ZnS:Mn/CdS核壳结构纳米微粒的制备及光学特性

采用微乳液法制备了掺Mn的ZnS纳米微粒并用CdS对其进行了表面修饰,以XRD、紫外吸收和发射光谱对其结构及光学性质进行了表征和研究.制得的纳米微晶粒径为4～6nm,为立方纤锌矿结构.与未经包覆的ZnS:Mn纳米微粒相比,核壳结构的ZnS:Mn/CdS纳米微粒中Mn2+发射峰的强度增强了很多,适当厚度的壳层的修饰可减少其表面态发射和非辐射跃迁,增强了Mn2+离子的4T1-6A1的能量传递和ZnS的带边发射,提高了发光效率;讨论了ZnS核中Mn掺杂浓度对ZnS:Mn/CdS纳米微晶的光学性能的影响,发现当掺Mn浓度为4;时Mn2+发射峰的强度最大.     

ZnS∶Mn/CdS核壳结构纳米微粒的制备及光学特性

采用微乳液法制备了掺Mn的ZnS纳米微粒并用CdS对其进行了表面修饰,以XRD、紫外吸收和发射光谱对其结构及光学性质进行了表征和研究。制得的纳米微晶粒径为4～6nm,为立方纤锌矿结构。与未经包覆的ZnS∶Mn纳米微粒相比,核壳结构的ZnS∶Mn/CdS纳米微粒中Mn2+发射峰的强度增强了很多,适当厚度的壳层的修饰可减少其表面态发射和非辐射跃迁,增强了Mn2+离子的4T1—6A1的能量传递和ZnS的带边发射,提高了发光效率;讨论了ZnS核中Mn掺杂浓度对ZnS∶Mn/CdS纳米微晶的光学性能的影响,发现当掺Mn浓度为4%时Mn2+发射峰的强度最大。     

Ag/ZnS核壳结构纳米棒的制备及其光催化性能分析

在制备的Ag纳米线的基础上,用水热法合成了Ag/ZnS核壳结构纳米棒.使用X射线衍射仪(XRD)、场发射扫描电子显微镜(FESEM)、X射线能谱仪(EDS)、高分辨透射电子显微镜(HRTEM)、紫外-可见双光束分光光度计(UV-vis)、光致发光扫描仪(PL)等检测设备对样品的成分、形貌、微结构及光学性能进行了表征.结果显示,制备的Ag/ZnS复合材料为ZnS纳米颗粒包覆Ag纳米线的核壳结构,其紫外吸收峰位于350 nm处,相对于ZnS纳米颗粒变宽并发生红移,PL发射峰位于462 nm处,相对于ZnS纳米颗粒发生了蓝移,强度明显降低.光催化结果显示,Ag/ZnS核壳结构纳米棒的光催化性能优于ZnS纳米颗粒,分析了光催化反应机理.     

Er掺杂ZnS纳米晶的合成及光致发光性能研究

以巯基乙酸(HSCH2COOH)为稳定剂,采用水热法合成了分散性好的ZnS∶ Er纳米晶,分别利用XRD、TEM,荧光光谱仪对其物相,形貌及光学性能进行了研究.结果表明:ZnS∶ Er纳米晶为闪锌矿ZnS结构,颗粒近似球形,平均粒度为5 ～8 nm.当Er3+掺杂摩尔浓度为6;,稳定剂巯基乙酸添加摩尔分数为2;,合成温度为120℃条件下得到了发光性能较好的Er离子掺杂ZnS纳米晶材料,并对其发光机理进行了探讨.     

声化学法合成ZnS纳米晶及反应动力学研究

采用声化学法制备了ZnS纳米晶,对其反应动力学进行了研究,利用XRD、TEM等手段对样品进行了表征.结果表明,以无水氯化锌、硫代乙酰胺为原料,采用声化学法可以制备粒径在10 nm左右的ZnS纳米晶,所得样品为α-ZnS纤锌矿结构,六方晶系,形貌为球形或近球形.随超声功率增加,ZnS纳米晶粒度降低.动力学研究表明,ZnS纳米晶的生成量随时间呈线性增加,ZnS纳米晶的生成活化能为29.88 kJ/mol.     

声化学法制备ZnS: Mn纳米晶及其光学性能

以无水氯化锌,四水氯化锰以及硫代乙酰胺为原料,采用声化学法成功制备了锰掺杂的ZnS(ZnS: Mn)纳米晶.采用透射电子显微镜镜(TEM)、X射线能谱仪(EDS)、X射线粉末衍射(XRD)和光致发光谱(PL)对所制得的纳米进行了表征.结果表明:所制备ZnS: Mn为立方闪锌矿结构,纳米粒子的形貌接近于球形.平均晶粒尺寸为10 nm左右.PL光谱分析表明:所制备试样有两个主要的发射峰,分别位于在480 nm和570 nm左右,后者与体材料ZnS: Mn相比发生了明显蓝移,但仍表现为橙黄色发光.Mn2+掺杂浓度对ZnS: Mn的光致发光性能有显著影响,原料中Zn: Mn: S(物质的量比)为3: 1: 4,Mn2+掺杂浓度为2.64 at;时,光致发光光谱发射峰强度达到最大值.     

L-半胱氨酸修饰的ZnS∶Co/ZnS量子点的合成及表征

选用L-半胱氨酸作为修饰剂,采用共沉淀法在水溶液中合成了ZnS∶ Co/ZnS量子点.通过X-射线粉末衍射(XRD)、透射电镜(TEM)、红外光谱(IR)、紫外可见光谱(UV-Vis)和荧光光谱(PL)对量子点的结构、形貌、组成及光谱性质进行表征.结果表明:ZnS∶ Co/ZnS量子点为立方闪锌矿结构,颗粒呈球形,分散性好,颗粒尺寸约为3.3nm1;随着ZnS壳层增厚,ZnS∶ Co/ZnS量子点的荧光发射峰强度先增大后减小,核壳比为1∶0.15时发光强度达到最大.Co2+的掺杂和ZnS壳层的形成使量子点的荧光量子产率从2.4;增加到9.8;.L-半胱氨酸分子通过其巯基与量子点表面的金属离子配位,从而修饰在量子点的表面,使该量子点具有水溶性、生物相容性和生物可偶联性.     

脉冲电沉积结合水热法制备ZnS纳米条及其光学性质的研究

用水热法在脉冲电沉积纳米ZnS晶种的衬底上,制备了ZnS纳米条.利用XRD、SEM、EDS对ZnS的形貌和结构进行了表征,通过UV、PL研究了ZnS的光学性质.结果表明,ZnS晶种的存在、形貌控制剂(5-磺基水杨酸)的添加对ZnS显微形貌和光学性质有重大影响.重点讨论了形貌控制剂的添加顺序对ZnS形貌的影响.产物ZnS为闪锌矿结构,发蓝光,组成均匀,对紫外光的透过率较低,光学禁带宽度变宽.     

One‐step green synthesis by organic molten salt method and optical properties of CdS nanosheets

Cadmium sulfide (CdS) nanosheets were synthesized by an environment friendly, “green” organic molten salt (OMS) method at 220 °C. The as‐synthesized products were characterized by X‐ray diffraction (XRD), scanning electron microscopy (SEM), Transmission electron microscopy (TEM) and energy dispersive spectroscopy (EDS), respectively. The XRD results reveal that the as‐synthesized CdS nanosheets are of the hexagonal wurtzite structure and the CdS nanosheets grow along the c‐axis. The SEM results indicate that the diameters and thickness of the CdS nanosheets are about 20–40 nm and 5–10 nm, respectively. The optical properties of the CdS nanosheets were investigated by ultraviolet–visible (UV‐Vis) spectroscopy and photoluminescence (PL) spectroscopy. The ultraviolet–visible spectrum exhibits two excitonic peaks with a step‐like absorption and the photoluminescence spectrum shows a green emission peak centered at around 524 nm. A possible growth mechanism of CdS nanosheets was discussed.     

溶剂热法制备双螺旋ZnS纳米结构研究

采用溶剂热法以醋酸锌和硫化钠反应成功制备了具有双螺旋结构的一维ZnS纳米棒,利用X射线衍射(XRD)、高分辨透射电子显微镜(HRTEM)、选区电子衍射(SAED)、X射线能量色散分析谱仪(XEDS)、紫外吸收光谱(UV-vis)和光致发光谱(PL)等测试手段对样品的化学成分、形貌、晶体结构和光学性质等进行了表征分析.实验结果表明样品为一维六方纳米晶结构,沿着[001]方向生长,并具有双螺旋结构,长度分布在100～200 nm范围,直径约为5 ～15 nm,螺距约为20 nm.双螺旋ZnS纳米结构的吸收峰与块体材料相比发生了蓝移.     

ITO玻璃衬底上生长的Zn0.9Mg0.1S多晶薄膜特性研究

以ZnS和Mg粉末为原料,采用真空蒸镀技术在ITO玻璃上成功地制备了宽禁带三元化合物Zn0.9Mg0.1S多晶薄膜.原子力显微镜和X射线衍射研究表明:薄膜生长形貌和结晶性能良好,为择优取向的立方闪锌矿结构,晶粒直径约20nm,薄膜的X射线衍射峰较之ZnS的衍射峰向大角度方向移动了0.46°;室温下的拉曼谱峰相对于ZnS的拉曼谱峰出现蓝移,且347.67cm-1谱峰比较强;光致发光谱显示,Zn0.9Mg0.1S薄膜在410nm处有一个较强的发光峰.良好的结晶质量和发光特性为开发多功能材料和器件提供了可能性.     

Synthesis and characterization of PbSe and PbSe/PbS core–shell colloidal nanocrystals

A new colloidal procedure, for the synthesis of PbSe and PbSe/PbS core–shell semiconductor nanocrystals (NCs), is reported. The synthesis includes the reaction between tributyl-phosphine selenium and lead 2-ethyl-hexanoate, under inert gas at room temperature. High-resolution transmission electron microscopy (HRTEM), X-ray energy dispersive spectroscopy (EDS), absorption and photoluminescence (PL) spectroscopy were used to characterize the samples. The EDS and HRTEM confirmed the existence of rock-salt cubic structures of the PbSe. Furthermore, the HRTEM showed the formation of PbSe/PbS core–shell structures, with epitaxial shell layer with thickness varying between 1 and 4 ML. The absorption spectra of these materials exhibited distinct transitions, related to the e1–h1, e2–h2 and e2–h3 and e2–h1 transitions. These bands are blue shifted with decrease in the NCs diameter. However, the e1–h1 is slightly red shifted with increase in the PbS shell thickness. The last effect can be due to an electronic mixing of the PbSe and PbS conduction states. The PL measurements showed a substantial increase of the exciton emission in the core–shell structures, arising by an efficient chemical passivation of the PbSe core.     

Optical properties of flower‐like CdS prepared by a hydrothermal method with SDBS as surfactant

In this article, flower‐like CdS structures have been prepared by a hydrothermal method with SDBS as surfactant. The influences of different experimental conditions on the morphologies, UV‐Vis and fluorescence properties of CdS have been investigated. The performances of CdS have been analyzed by X‐ray diffraction (XRD), field emission scanning electron microscopy (FESEM), ultraviolet‐visible (UV–Vis) and room‐temperature photoluminescence (PL). The XRD result indicates that the flower‐like CdS structures are of hexagonal phase. The FESEM results indicate that the main role of SDBS is to make the CdS crystals assemble together to form the flower‐like structures. The UV–Vis results show CdS has a strong absorption in the ultraviolet region and visible‐light region. The PL results show CdS has two emission peaks, respectively at 461 nm and 553 nm. The growth mechanism for the formation of flower‐like CdS structures is also described.     

硫化锌微米球的水热合成和光催化性能

采用简单的低温水热法成功合成了硫化锌微球.利用X射线衍射(XRD)、场发射扫描电镜(FESEM)、透射电镜(TEM)、光催化、光致发光(PL)和紫外-可见吸收光谱(UV-Vis)技术对ZnS样品的结构、形貌及光学和光催化性能进行表征和分析.结果表明ZnS微米球为立方闪锌矿,所制备样品的PL发射中心位于468 rn,室温UV -Vis吸收峰位于276.5nm.光催化性能显示,在自然光照射1h时,甲基橙的降解率达到93.15;.实验制备的硫化锌样品具有较好的光催化性能和应用前景.     

Synthesis and characterization of semiconductor metal sulfide nanocrystals using microemulsion technique

The semiconductor nanocrystals ZnS, PbS, CdS and CuS were synthesized via microemulsion technique involving metal acetate, reducing agent (Na₂S) and Triton X‐100 as surfactant. Nanocrystals were characterized by X‐ray diffraction (XRD), transmission electron microscopy (TEM) and dynamic light scattering (DLS). The average size of ZnS, PbS, CdS and CuS nanocrystals were found to be 5.6 nm, 13.3 nm, 11.4 nm and 6.2 nm, respectively. Different parameters like surfactant (Triton X‐100) concentration, water‐to‐surfactant ratio (ω), precursor concentration [zinc acetate, (Zn(AC)₂], reducing agent concentration [sodium sulphide, (Na₂S)] were optimized to synthesize ZnS quantum dots.     

表面活性剂对水热法合成ZnS:Cu,Al纳米晶光致发光特性的影响

采用水热法直接合成了ZnS∶Cu,Al纳米荧光粉,并且系统研究了加入表面活性剂在不同S/Zn下,清洗样品和不清洗样品的结晶性、傅立叶红外光谱(FT-IR)及光致发光(PL)光谱.XRD和TEM测试结果表明:合成纳米晶为纯立方相结构,球形纳米晶尺寸约15 nm, 尺寸分布窄,分散性好.未清洗样品的结晶性比清洗样品的好,且加入表面活性剂和未清洗都导致粒径增大,影响纳米材料的表面态.改变[S~(2-)]/[Zn~(2+)]物质的量比、清洗和加入表面活性剂都会影响材料的PL强度.这说明其发光机理为紫外光激发材料表面的发光中心,即PL强度决定于纳米材料的表面态.