CdO—SnO2复合氧化物的组成与性能

通过控制共沉淀时溶液中Ｃｄ／Ｓｎ摩尔比的方法，合成了物相组成不同的ＣｄＯ－ＳｎＯ２复合氧化物粉料，探讨了相组成与材料电导及气敏性能之间的关系。     

一些无机盐对甲烷的液相选择催化氧化

考察了无机盐Ｃｒ２（ＳＯ４）３，ＣｄＳＯ４，ＦｅＳＯ４，ＶＯＳＯ４，Ｃｅ（ＳＯ４）２，ＭｎＳＯ４，ＳｎＣｌ４和ＨｇＳＯ４在浓硫酸介质中对甲烷的催化活性，发现ＭｎＳＯ４，ＳｎＣｌ４和ＨｇＳＯ４对甲烷氧化有活性，在此基础上考察了ＨｇＳＯ４体系中气液体积比，温度，浓度，反应时间以及硫酸浓度地反应活性的影响，认为反应按亲电取代反应机理进行。     

混合微乳液的增敏作用研究：Cd（Ⅱ）—5—Br—PADAP的分光光度测定

研究了在Ｏ／Ｗ混合微乳液ＳＤＳ－ＯＰ／ｎＣ４Ｈ９ＯＨ／ｎ－Ｃ７Ｈ１６／Ｈ２Ｏ介质中，Ｃｄ（Ⅱ）－５－Ｂｒ－ＰＡＤＡＰ的显色反应。结果表明显色反应的灵敏度较单一的ＳＤＳ微乳液，单一的ＯＰ的微乳液，混合ＳＤＳ－ＯＰ胶束的介质中，具有更好的增敏作用和稳定性，Ｃｄ浓度在０－５μｇ／１００ｍＬ范围内符合比尔定律。方法用于废水和环境水样中微量Ｃｄ的测定，结果满意。     

含氧酸离子RO_4~(n-)中的p-dπ配键

引用对ＲＯｎ－４（Ｒ＝Ｃｌ，Ｓ，Ｓｅ，Ｔｅ，Ｐ，Ｓｉ）进行ＣＮＤＯ计算结果定量说明Ｒ—Ｏ键中存在较强的ｐｄπ配键，并讨论了与ｐｄπ配键密切相关的无机含氧酸及其盐的热稳定性、含氧酸的酸性及ＲＯｎ－４离子的聚合作用。     

掺锑CdSnO3体系的固溶与导电机制研究

按ＣｄＳｂｘＳｎ１－ｘＯ３进行化学量配比，以化学共沉淀法制得系列掺锑ＣｄＳｎＯ３固溶体粉料．ＸＲＤ分析结果表明，掺锑固溶的ｘ值范围为０＜ｘ＜０．３．研究固溶体组成与电导的关系发现：随着锑离子的溶入，材料的电阻先是较大程度地降低，然后再缓慢升高，并在掺锑固溶量的ｘ值为０．０２和０．２５时，分别出现了两个电阻最低点．探讨了体系的固溶性与导电机制．     

RE（NO3）3与丝氨酸间配合行为的半微量相平衡研究

测定了ＲＥ（ＮＯ３）３－Ｓｅｒ－Ｈ２Ｏ（ＲＥ＝Ｓｍ，Ｇｄ，Ｙｂ）三元体系在２５℃的溶度和饱和溶液折光率，各体系的溶度曲线和饱和溶液折光曲线均由四支组成，分别与ＲＥ（ＮＯ３）３．ｎＨ２Ｏ（ＲＥ＝Ｓｍ，Ｇｄ，ｎ＝６；ＲＥ＝Ｙｂ，ｎ＝５）配合物ＲＥ（Ｓｅｒｉｍｅ）（ＮＯ３）３．４Ｈ２Ｏ（一致溶解化合物），ＲＥ（Ｓｅｒｉｎｅ）４（ＮＯ３）３．６Ｈ２Ｏ（不一致溶解化合物）和Ｓｅｒｉｎｅ相对应。     

Ln（ClO4）3—DAPTU—H2O三元体系30℃时的相平衡研究

测定了Ｌｎ（ＣｌＯ４）３－ＤＡＰＴＵ－Ｈ２Ｏ（Ｌｎ＝Ｌｎ，Ｓｍ，Ｙｂ）三元体系在３０℃时的溶解度及饱和溶液的折光率，绘制了相应的溶度图和折光率－组成图。各体系的溶度曲线和折光率曲线均由三支组成，分别与ＤＡＰＴＵ、Ｌｎ（ＤＡＰＴＵ）２（ＣｌＯ４）３·８Ｈ２Ｏ（Ｌｎ＝Ｌａ，Ｓｍ，Ｙｂ）和Ｌｎ（ＣｌＯ４）３·ｎＨ２Ｏ（Ｌｎ＝Ｌａ，ｎ＝８；Ｓｍ，ｎ＝９；Ｙｂ，ｎ＝８）相对应。从溶度图上发现了３个未见文献报     

Ce掺杂对SnO2薄膜电学及气敏性能的影响

以无机盐ＳｎＣｌ２．２Ｈ２Ｏ（Ｎ４）３Ｃｅ（ＮＯ３）６为原料，无水乙醇为溶剂，采用溶胶－凝胶工艺制备了纯ＳｎＯ２及ＳｎＯ２：Ｃｅ薄膜。研究了ＳｎＯ２：Ｃｅ薄膜的热分解晶化过程和Ｃｅ掺杂和ＳｎＯ２薄膜的及气敏性能的影响，发现ＳｎＯ２：Ｃｅ薄膜在常温下对Ｈ２Ｓ气体具有较妇的敢敏性能，对ＳｎＯ２：Ｃｅ薄膜的结构进行了表征。     

LaCaMnO3催化剂活性相的结构和形成机理的研究

利用ＴＧ，ＤＴＡ，ＸＲＤ和ＸＰＳ方法研究了Ｌａ０．２Ｃａ０．８ＭｎＯ３催化剂的结构和形成机理。样品用Ｌａ，Ｃａ，Ｍｎ混合硝酸盐制备。随着焙烧温度的升高发生的一系列的固相反应，发现氨氧化催化剂催化活性与生成的ＣａＭｎＯ３含量成正比。在９００℃制备的含有ＣａＭｎＯ３，Ｌａ０．５７５Ｃａ０．４２５ＭｎＯ３，Ｍｎ２Ｏ３和Ｌａ２Ｏ３的混合物是氨氧化最佳催化剂，活性相是ＣａＭｎＯ３，并具有大量的氧空穴。     

Ln（ClO_4）_3－DAPTU－H_2O三元体系30℃时的相平衡研究

测定了Ｌｎ（ＣｌＯ_４）_３－ＤＡＰＴＵ－Ｈ_２Ｏ（Ｌｎ＝Ｌａ，Ｓｍ，Ｙｂ）三元体系在３０℃时的溶解度及饱和溶液的折光率，绘制了相应的溶度图和折光率－组成图，各体系的溶度曲线和折光率曲线均由三支组成，分别与ＤＡＰＴＵ、Ｌｎ（ＤＡＰＴＵ）_２（ＣｌＯ_４）_３·８Ｈ_２Ｏ（Ｌｎ＝Ｌａ，Ｓｍ，Ｙｂ）和Ｌｎ（ＣｌＯ_４）_３·ｎＨ_２Ｏ（Ｌｎ＝Ｌａ，ｎ＝８；Ｓｍ，ｎ＝９；Ｙｂ，ｎ＝８）相对应。从溶度图上发现了３个未见文献报道的固液异组成溶解的化合物，通过化学分析及元素分析、ＴＧ－ＤＴＧ、ＩＲ对其进行了表征。     

In situ template synthesis of SnO nanoparticles on nickel foam with high electrochemical performance

A solution strategy performed at room temperature was presented for the in situ synthesis of SnO nanoparticles. SnO nanoparticles were prepared through the following sequent procedure: (1) preparation of rod-like Cd(OH)Cl utilizing the reaction between Cd²⁺ ions and epoxide; (2) production of Sn₂₁Cl₁₆(OH)₁₄O₆ template through the cation exchange reaction between Cd(OH)Cl and Sn²⁺ ions; (3) formation of SnO nanoparticles on nickel foam by the in situ reaction in strong alkaline electrolyte solution before electrochemical measurement. The as-prepared SnO had very small particle size and ordered nanostructure of particulate sheet, therefore resulting in its excellent electrochemical performance including high specific capacitance and high electrochemical stability for the charge-discharge cycle. Hence, the SnO nanoparticles synthesized in this work could be considered as one promising metal oxide for the utilization as electrode material in supercapacitor.

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SnO nanoparticles were prepared by an in situ template strategy. The synthetic procedure included the production of rod-like Cd(OH)Cl precursor at room temperature, preparation of platelet-like Sn₂₁Cl₁₆(OH)₁₄O₆ template through a cation exchange reaction, and the in situ synthesis of SnO nanoparticles from the template on nickel foam. Due to the small particle size, SnO presented high electrochemical performance as electrode material for application in supercapacitor.

     

复合纳米微粒Rh3+/TiO2/SnO2的合成、表征及光催化降解4-(2-吡啶偶氮)间苯二酚的研究

采用溶胶 凝胶法制备复合纳米微粒Rh³⁺/TiO₂/SnO₂作系列光催化剂,运用BET、XRD等技术对样品进行了表征.讨论了影响污染物4 (2 吡啶偶氮)间苯二酚(PAR)光催化降解率的主要因素,实验结果表明:以Rh³⁺/TiO₂/SnO₂为复合光催化剂,当m(TiO₂)∶m(SnO₂)=56:44,ω(Rh³⁺)=2.0%,催化剂用量为1.0 g,通入空气的流量为10.0 L/min,试液的质量分数为2.0×10^-6,pH=7.0时,光照2h,PAR的降解率达到96.2%.     

FT-IR and FT-Raman study of Nasicon type phosphates, ASnFe(PO4)3 [A=Na2, Ca, Cd

FT-Raman and FT-IR spectra of ASnFe(PO4)3 [A=Na2, Ca, Cd] were recorded and analyzed. The bands were assigned in terms of the vibrational group frequencies of SnO6 octahedral and PO4 tetrahedral. The spectral analysis shows that the symmetry of corner shared octahedral (SnO6) and the tetrahedral (PO4) are lowered from their free ion symmetry state. The presence of Fe3+ ions disrupts the S-N-O-S-N chain in the structure. This causes distortion of SnO6 and PO4 in the structure of all the compounds. Also it is seen that there are two distinct PO4 tetrahedra of different P-O bond lengths. One of these tetrahedra is linearly distorted in all the title compounds. The PO4 frequencies and bond lengths are calculated theoretically and are in agreement with the experimental values. The presence of PO4 polyanion in the structure can reduce the redox energy and hence reduce the metal oxygen covalency strength in the structure.     

石墨/氧化锡/活性炭锂离子电池负极材料的合成及性能

采用液相法,以SnCl2·2H2O、石墨、活性炭为原料,在油浴中共热合成石墨/氧化锡/活性炭复合材料.通过XRD和电化学测试对材料进行了表征.结果表明,样品中含有石墨和金红石SnO2·这种材料作为锂离子电池负极材料具有良好的充放电循环性能.     

Optical and photocatalytic properties of heavily F(-)-doped SnO2 nanocrystals by a novel single-source precursor approach

Heavily F-doped SnO(2) nanocrystals were successfully prepared by a novel synthetic approach involving low-temperature oxidation of a Sn(2+)-containing fluoride complex KSnF(3) as the single-source precursor with H(2)O(2). The F-doped SnO(2) powder was characterized by powder X-ray diffraction, TG-MS, BET surface area, diffuse reflectance spectroscopy, XPS, PL, FTIR spectroscopy, Raman spectroscopy, EPR spectroscopy, SEM, and TEM. Broadening of the diffracted peaks, signifying the low crystallite size of the products, was quite evident in the powder X-ray diffraction pattern of SnO(2) obtained from KSnF(3). It was indexed in a tetragonal unit cell with lattice constants a = 4.7106 (1) ? and c = 3.1970 (1) ?. Agglomeration of particles, with an average diameter of 5-7 nm, was observed in the TEM images whose spotwise EDX analysis indicated the presence of fluoride ions. In the core level high-resolution F 1s spectrum, the peak observed at 685.08 eV was fitted by the Gaussian profile yielding the fluoride ion concentration to be 21.23% in the SnO(2) lattice. Such a high fluoride ion concentration is reported for the first time in powders. SnO(2):F nanocrystals showed greater thermal stability up to 300 °C when heated in a thermobalance under flowing helium, after which generation of small quantities of HF was observed in the TG coupled mass spectrometry analysis. The band gap value, estimated from the Kubelka-Munk function, showed a large shift from 3.52 to 3.87 eV on fluoride ion doping, as observed in the diffuse reflectance spectrum. Such a large shift was corroborated to the overdoped situation due to the Moss-Burstein effect with an increase in the carrier concentration. In the photoluminescence (PL) spectrum, SnO(2):F nanocrystals exhibited a broad green emission arising from the singly ionized oxygen vacancies created due to higher dopant concentration. The evidence for singly ionized vacancies was arrived from the presence of a signal with a g value of 1.98 in the ESR spectrum of SnO(2):F at room temperature. The disordered nature of the rutile lattice and the enormous oxygen vacancies created due to fluoride ion doping were evident from the broad bands observed at 455, 588, and 874 cm(-1) in the room-temperature Raman spectrum of SnO(2):F. As the consequence of the oxygen vacancies, F-doped SnO(2) was examined for the function as a photocatalyst in the degradation of aqueous RhB dye solution under UV irradiation. A very high photocatalytic efficiency was observed for the F-doped SnO(2) nanocrystals as compared to pure SnO(2). The BET surface area of pure SnO(2) was quite high (207.81 m(2)/g) as compared to the F-doped SnO(2) nanocrystals (45.16 m(2)/g). Pore size analysis showed a mean pore diameter of 1.97 and 13.97 nm for the pure and doped samples. The increased photocatalytic efficiency was related to the very high concentration of oxygen vacancies in SnO(2) induced by F doping.     

Density functional theory study on the structural and electronic properties of low index rutile surfaces for TiO2/SnO2/TiO2 and SnO2/TiO2/SnO2 composite systems

The present study is concerned with the structural and electronic properties of the TiO2/SnO2/TiO2 and SnO2/TiO2/SnO2 composite systems. Periodic quantum mechanical method with density functional theory at the B3LYP level has been carried out. Relaxed surface energies, structural characteristics and electronic properties of the (110), (010), (101) and (00) low-index rutile surfaces for TiO2/SnO2/TiO2 and SnO2/TiO2/SnO2 models are studied. For comparison purposes, the bare rutile TiO2 and SnO2 structures are also analyzed and compared with previous theoretical and experimental data. The calculated surface energy for both rutile TiO2 and SnO2 surfaces follows the sequence (110) < (010) < (101) < (001) and the energy increases as (010) < (101) < (110) < (001) and (010) approximately = (110) < (101) < (001) for SnO2/TiO2/SnO2 and TiO2/SnO2/TiO2 composite systems, respectively. SnO2/TiO2/SnO2 presents larger values of surface energy than the individual SnO2 and TiO2 metal oxides and the TiO2/SnO2/TiO2 system renders surface energy values of the same order that the TiO2 and lower than the SnO2. An analysis of the electronic structure of the TiO2/SnO2/TiO2 and SnO2/TiO2/SnO2 systems shows that the main characteristics of the upper part of the valence bands for all the studied surfaces are dominated by the external layers, i.e., by the TiO2 and the SnO2, respectively, and the topology of the lower part of the conduction bands looks like the core layers. There is an energy stabilization of both valence band top and conduction band bottom for (110) and (010) surfaces of the SnO2/TiO2/SnO2 composite system in relation to their core TiO2, whereas an opposite trend is found for the same surfaces of the TiO2/SnO2/TiO2 composite system in relation to the bare SnO2. The present theoretical results may explain the growth of TiO2@SnO2 bimorph composite nanotape.     

CO为还原剂同时还原SO2和NO的SnO2-TiO2固溶体催化剂Ⅱ.催化剂的物理化学性质

 用XRD, XPS, CO-TPR, NH3-TPD, SO2-TPD和IR等方法表征了SnO2-TiO2固溶体催化剂的物理化学性质. 不同配比的SnO2和TiO2均可形成均一的具有金红石结构的连续固溶体,其晶粒度比单纯的SnO2或TiO2的晶粒度小. SnO2-TiO2固溶体的比表面积随SnO2含量的增大呈火山形变化,说明在SnO2-TiO2固溶体中SnO2可阻止TiO2由锐钛矿型变为金红石型过程中比表面积的减小,而TiO2则提供了维持大表面的结构框架. SnO2倾向于在固溶体表面偏析,固溶体的表面氧含量高于单纯SnO2的表面氧含量而低于单纯TiO2的表面氧含量. SnO2, TiO2和SnO2-TiO2表面含有能被CO还原的吸附氧和晶格氧,被还原的SnO2, TiO2和SnO2-TiO2的表面晶格氧的数量仅占所有晶格氧的0.001%, 说明CO只使部分晶格氧还原并生成氧阴离子空穴. TiO2表面没有酸性, SnO2和SnO2-TiO2呈微弱酸性. 经CO还原的SnO2-TiO2上存在大量的强碱中心,说明SnO2和TiO2之间发生了协同作用. SnO2-TiO2固溶体的这些物化性质均十分有利于SO2+NO+CO的氧化还原反应.     

纳米SnO2@TiO2包覆催化剂的制备及表征

采用活性层包覆法在自制细SnO2胶体粒子表面包覆TiO2,制备出SnO2@TiO2包覆型复合催化剂,以其对有机磷农药DDVP的降解效果作为评价光催化活性的标准,对制备条件进行了优化,并用XRD、TEM和BET等手段对样品进行了表征,结果表明,SnO2胶体乙醇溶液含水量20％,钛酸丁酯质量分数为34.5％。灼烧温度680℃时制得TiO2含量56.45％的包覆样品SnO2@TiO2为纳米级粒子,且其光催化活性最佳。     

氧化锡和氧化锌双层薄膜的XPS研究

用XPS法研究了SnO2 /ZnO及ZnO/SnO2 双层膜中锌和锡的扩散情况 ,结果表明 :锌在SnO2中的扩散比锡在ZnO中的扩散更容易。讨论了锌在SnO2 层中的扩散方式和扩散的结果。在ZnO层留下了较多的氧 ,并使部分的SnO2 还原为SnO。     

CoPc（β-OC6Cl5）4/SnO2复合材料的制备及光催化性能研究

用原位合成的方法制备不同物质的量配比的CoPc(β-OC6Cl5)4/SnO2复合材料,利用UV,IR和XRD对产物进行表征,并在可见光条件下测定其对罗丹明B光催化降解反应产率.结果表明:复合材料在紫外光谱中出现红移现象,红外光谱中出现了M—O的振动吸收峰,XRD谱图中显现出SnO2晶粒变小,说明CoPc(β-OC6Cl5)4与SnO2之间形成部分化学键,负载量物质的量分数为4%的CoPc(β-OC6Cl54)/SnO2复合材料对罗丹明B的光催化降解产率最高.