溶致液晶中金属纳米粒子的掺杂及其作用机制研究

在用琥珀酸二异辛酯磺酸钠(AOT)构建的具有长程有序结构的层状溶致液晶内, 用不同方式导入预制的亲油或亲水贵金属纳米粒子, 可得到纳米粒子分布在不同介观空间内的无机/有机杂合体. 依据小角X射线散射和偏光显微镜结果, 通过分析掺杂纳米粒子与液晶模板的相互作用, 对掺杂前后体系结构的变化及制得杂合体的稳定性进行了表征. 结果表明, 除考虑掺杂粒子与层状模板空间的匹配外, 体系中静电斥力、范德华引力和Helfrich涨落力之间的平衡是维持液晶结构稳定的基本条件.     

Ni,Ru掺杂CePO4纳米材料的合成与仿酶性质

通过水热方法合成了具有高比表面积的Ni, Ru掺杂CePO₄纳米粒子(NiRu-CePO₄). 结合纳米粒子的X射线衍射(XRD)、 扫描电子显微镜(SEM)、 透射电子显微镜(TEM)和X射线能谱(EDX)的表征结果发现, NiRu-CePO₄符合六方相磷酸铈, 纳米粒子长轴尺寸约为20 nm, Ni和Ru均匀分布于纳米CePO₄中; 样品的BET表面积高达178.4 m²/g, ζ电势为-18.2 mV. 以3,3',5,5'-四甲基联苯胺(TMB)作为电子供体和显色剂, 通过分光光度法监测652 nm处的吸光度值对产物浓度进行分析, 结果表明, NiRu-CePO₄催化剂在宽泛的pH范围内表现出类过氧化物酶和类氧化酶活性. 对催化后的催化剂进行表征, 发现样品形貌、 元素分散性和表面Ce的价态均未显著变化, 表明NiRu-CePO₄具有较高的稳定性.     

Ir/ZrO2催化剂对甲烷催化燃烧性能的研究

采用浸渍法制备了ZrO₂为载体负载Ir的催化剂(Ir/ZrO₂), 考察了催化剂的CH₄催化燃烧性能. 采用X射线衍射(XRD), 拉曼光谱(Raman), X射线光电子能谱(XPS), 氢气程序升温还原(H₂-TPR)等技术对催化剂的结构和Ir物种的存在形式进行了表征. 结果表明, Ir/ZrO₂催化剂中Ir是以IrO₂形式存在的, Ir/ZrO₂催化剂的CH₄燃烧表观活性随着Ir负载量的增加而提高, 并且催化剂表现出较高的催化活性和良好的反应稳定性. 在低Ir负载量(≤1%)时, CH₄燃烧的转换频率(TOF)随着Ir粒子的增大而提高|然而高Ir负载量(≥1%)时, TOF随着Ir粒子的增大保持不变.     

助溶剂对L64/咪唑离子液体聚集体的影响

利用偏光显微镜(POM)和小角X射线散射(SAXS)技术研究了不同极性的助溶剂对嵌段聚合物L64(PEO₁₃PPO₃₀PEO₁₃,PEO：聚氧乙烯；PPO：聚氧丙烯)和1-丁基-3-甲基咪唑四氟硼酸盐(^[Bmim][BF₄])形成的层状液晶结构的影响。极性较小的对二甲苯、庚烷、环己烷和异辛烷均可少量增溶于层状液晶中，并使得液晶的结构更有序。极性较大的水分子与L64和[Bmim][BF₄]之间均可形成氢键和静电作用力，这种竞争性作用力，使得L64和[Bmim][BF₄]之间的静电作用力减弱，层状液晶结构被破坏。基于液晶纹理织构和SAXS谱图，提出了助溶剂对层状液晶结构影响的作用机理。     

3d过渡金属掺杂TiO2纳米晶膜电极的光电化学研究

应用原子力显微镜和X射线粉末法对3d过渡金属离子Cr(Ⅲ),Fe(Ⅲ),Mn(Ⅱ),Co(Ⅱ),Ni(Ⅱ),Cu(Ⅱ)和Zn(Ⅱ)掺杂TiO₂纳米晶粒(简写为m^3d-TiO₂)作了表征,并用光电化学方法研究了m^3d-TiO₂纳米结构多孔膜电极.实验结果表明,m^3d-TiO₂纳米粒子的颗粒较均匀,粒径约为15nm,其晶型为锐钛矿和板钛矿的混晶.在所研究的m^3d-TiO₂中,只有Zn²⁺-TiO₂电极的光电流大于未掺杂的TiO₂纳米结构多孔膜电极.3d金属离子的掺杂引起各电极的光电流信号在一定波长范围内出现p-n转型现象.     

液晶模板法制备Au纳米线

利用非离子表面活性剂C₁₂E₄的层状液晶作为模板,以氯金酸(HAuCl₄)水溶液作为体系的水相和反应物,并利用C₁₂E₄中EO基团的还原性制备了Au的纳米线.研究表明,反应物的浓度、液晶体系的组成和反应时间都将影响产物的形貌.在适当条件下,可以得到直径约为20nm,长度达到几微米的均匀金纳米线,并探讨了纳米线形成过程中层状液晶的模板作用.     

La3+掺杂CaFe2O4材料的制备及室温检测超低浓度甲醛

采用静电纺丝法成功制备了La³⁺掺杂CaFe₂O₄材料。通过X射线衍射、扫描电子显微镜和X射线光电子能谱对La³⁺掺杂CaFe₂O₄材料的结构和形貌进行了表征。随后,研究了La³⁺的掺杂量(质量分数)对CaFe₂O₄气敏性能的影响。研究表明,3%La³⁺掺杂CaFe₂O₄材料在室温下对100μL·L^-1甲醛的响应最高(R_a/R_g=14.1)。更为重要的是,对甲醛的最低检测限低至0.1 nL·L^-1,并且响应/恢复时间仅为4.3 s/8.4 s。     

层状液晶乳液的相行为

层状液晶乳液的相行为;层状液晶(LLC);相转变温度;示差扫描量热法(DSC);小角X射线衍射(SAXD)     

铕掺杂TiO2的制备及其可见光光催化性能研究

采用溶胶-凝胶法制备了不同铕(Eu)掺杂量的TiO₂纳米颗粒(Eu-TiO₂),利用透射电镜(TEM),X射线光电子能谱(XPS),X射线衍射(XRD)及紫外可见漫反射(UV-Vis DRS)等方法对Eu-TiO₂进行了物理特性的初步表征.结果表明:与未掺杂纳米TiO₂比较,Eu-TiO₂禁带宽度变窄,具有可见光光催化活性.在可见光下(λ≥420 nm)照射下,以光催化降解染料罗丹明B(Rhodamine B,RhB)为目标反应,探讨了Eu-TiO₂不同制备条件对RhB降解光催化活性的影响,优化得到制备高活性Eu-TiO₂最佳pH为3、掺杂比例(n_Eu/n_Ti)为0.05%、煅烧温度为500 ℃.研究了可见光照射下Eu-TiO₂降解RhB和无色有机小分子水杨酸(SA)光催化反应条件及降解特性,RhB的12 h深度氧化矿化率为60.2%,SA的8 h降解率达到100%.通过跟踪测定可见光下Eu-TiO₂光催化反应过程中氧化物种的变化,研究了可见光激发Eu-TiO₂光催化反应机理,表明其光催化反应主要涉及羟基自由基(·OH)历程.     

具有开放骨架结构氟化磷酸钛的水热合成及分子动力学辅助确定骨架中模板剂的位置

在水热体系中,制备了一个具有三维开放骨架结构的氟化磷酸钛化合物Ti₄(PO₄)4(HPO₄)₂F₂.[(CH₃)₂N(CH₂)₂NH₃][H₃O](简称TP-J3J=Jilinuniversity).用X射线粉末衍射、元素分析、热重分析和X射线单晶衍射对其进行了表征.单晶结构分析表明,该化合物属于三斜晶系,P1空间群,晶胞参数a=0.6353(1)nm,b=0.8699(2)nm,c=1.1069(2)nm,α=93.94(3),β=90.13(3),γ=107.96(3),V=0.5804(2)nm³,Z=2,R₁=0.0391,wR₂=0.0959,GOF=1.052.TP-J3的骨架结构可以看作是由次级结构单元(SBU)[Ti₂(PO₄)₂(HPO₄)F]通过氧桥共顶点相连构筑而成的,在a和c方向形成了两种不同的八元环孔道,两种孔道相互交叉,形成了一种“类笼”结构.通过计算模拟确定双质子化的模板剂存在于“类笼”中,模板剂与骨架原子之间存在强烈的氢键作用,可稳定骨架的结构.     

Sol-gel preparation and spectroscopic study of the pyrophanite MnTiO_3 nanoparticles

Titanium dioxide (TiO2) is one of the green cata-lysts, which has attracted much attention due to its promising applications in the purification of air, the bactericidal action of water, and environmental photocatalytic degradation of organic pollutant co…     

油酸钠／水／十六烷／4-烯丙基-4羟基-1,6-庚二烯体系层状液晶的聚合

将十六烷增溶于油酸钠 /水体系层状液晶的油层 ,共聚单体 4 烯丙基 4 羟基 1 ,6 庚二烯增溶于油酸钠 /水体系层状液晶的两亲层 ,在同一两亲层内进行共聚反应 ,得到了具有层状结构、并具有较好表面活性的共聚物     

反相乳液中Ag/TiO2纳米杂化粒子的制备及其SERS效应

在反相乳液的微环境中用一步反应法制备了Ag/TiO2纳米杂化粒子,并用TEM,SPS,XPS及XRD等方法进行了表征.结果表明,Ag粒子(5-15nm)已镶嵌在TiO2(30-50nm)结构中,并且具有SERS活性.     

银掺杂介孔氧化铝抗菌剂的一步合成与表征

以Al(NO_3)_3·9H_2O和AgNO_3为原料,采用水热法制备了介孔氧化铝纳米粒子(Mesoporous Al_2O_3NPs)和银掺杂介孔氧化铝纳米粒子(Mesoporous Ag/Al_2O_3NPs),通过X射线衍射(XRD)、场发射扫描电子显微镜(FE-SEM)、X射线荧光光谱(XRF)、能量分散X射线衍射(EDX)和低温N2吸附-脱附等手段对产物进行了表征,通过最低抑菌浓度和抑菌圈实验研究了材料的抗菌性能.XRD分析表明在介孔Ag/Al_2O_3NPs中Al_2O_3是唯一结晶相,Ag掺杂后,介孔Ag/Al_2O_3NPs晶格常数和半高峰宽增大,晶面间距[(111),(400)和(440)面]减小.FE-SEM形貌分析表明掺杂后的介孔Ag/Al_2O_3NPs颗粒直径减小而孔径增大.EDX和XRF分析表明介孔Ag/Al_2O_3NPs中O/Al摩尔比为1.5,与Al_2O_3NPs中O/Al摩尔比相同.综合XRD和XRF分析结果认为,Ag进入介孔Al_2O_3晶格间隙形成间隙固溶体.低温N2吸附-脱附分析表明掺杂后的介孔Ag/Al_2O_3NPs比表面积、孔体积和孔径增大.曝气抗菌实验结果表明介孔Ag/Al_2O_3NPs的抗菌机理是活性氧和金属银的协同作用.介孔Ag/Al_2O_3NPs对革兰氏阴性菌(大肠杆菌)和革兰氏阳性菌(金黄色葡萄球菌)具有明显的抗菌效果,对大肠杆菌和金黄色葡萄球菌的最低抑菌浓度(MIC)均为80μg/m L,抑菌圈直径分别为26 mm和24 mm.     

Keggin结构钴取代硅钨酸盐聚苯胺掺杂材料的合成及性质

以Keggin结构钴取代杂多硅钨酸盐异构体α，β_i-K_6-nH_n[SiW₁₁Co(H₂O)O₃₉]·xH₂O( β_i=β₁，β₂，β₃)为掺杂剂，采用固相合成法制备了4种聚苯胺掺杂材料。用元素分析、红外光谱、紫外-可见光谱、SEM、X-射线粉末衍射、热重分析等对材料进行了表征，测定了材料的热稳定性、荧光性和导电性。实验结果表明：合成的掺杂态聚苯胺新材料具有较好的热稳定性、荧光性和导电性，室温电导率为7.5 × 10^-2 S·cm^-1，每种掺杂材料都有一个荧光发射峰，其发光中心来自于掺杂态聚苯胺极化子能带与价带之间的跃迁。     

Controllable synthesis, magnetism and solubility enhancement of graphene nanosheets/magnetite hybrid material by covalent bonding

Hybrids of Fe(3)O(4) nanoparticles and surface-modified graphene nanosheets (GNs) were synthesized by a two-step process. First, graphene nanosheets were modified by SOCl(2) and 4-aminophenoxyphthalonitrile to introduce nitrile groups on their surface. Second, the nitrile groups of surface-modified graphene nanosheets were reacted with ferric ions on the surface of Fe(3)O(4) with the help of relatively high boiling point solvent ethylene glycol to form a GNs/Fe(3)O(4) hybrid. The covalent attachment of Fe(3)O(4) nanoparticles on the graphene nanosheet surface was confirmed by Fourier-transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), energy-dispersive X-ray spectrometer (EDS) and scanning electron microscopy (SEM). TEM and HRTEM observations indicated that the sizes of the nanoparticles and their coverage density on GNs could be easily controlled by changing the concentration of the precursor and the weight ratio to GNs. Magnetic measurements showed that magnetization of the hybrid materials is strongly influenced by the reaction conditions. Chemically bonded by phthalocyanine, the solubility of as-synthesized GNs/Fe(3)O(4) hybrid materials was greatly enhanced, which was believed to have potential for applications in the fields of composites, wastewater treatment and biomaterials.     

Lamellar metal-organic complex and its rod-like nanoparticles prepared with ultrasonic technique

Metal-organic complex (H3NCH2CH2NH2)3[MoO2(OC6H4O)2] with a lamellar morphology has been syn- thesized. Its crystal structure was confirmed by single-crystal X-ray diffraction. The morphology of the crystal was observed by scanning electron microscopy (SEM). The metal-organic nanoparticles have been prepared by using an ultrasonic method. The morphology of the as-prepared nanoparticles was observed by transmission electron microscopy (TEM). The possible formation mechanism has also been proposed.     

Sc3+ 掺杂的尖晶石型LiMn2 O4 正极材料制备及性质

A series of Sc3+-doped spinel lithium manganese oxides Li1+xScyMn2-yO4（y=0.01, 0.02, 0.06, and 0.10）were synthesized by solid state reaction using LiOH·H2O, MnO2, and Sc2O3 as starting materials. The results of powder X-ray diffraction indicated that the doped Li1+xScyMn2-yO4 maintain the cubic structure of spinel phase Fd3m. The electrochemical properties were characterized by electrochemical methods. The initial discharge capacity reached 135 mAh/g and the capacity fading rate was less than 2% after 40 cycles. The spinel phase was well preserved after 40 cycles. The doping of Sc3+ effectively improved the cycleability of spinels, and was a promising way for the improvement of spinel LiMn2O4 cathode materials.     

Preparation and characterization of 4-dimethylaminopyridine-stabilized palladium nanoparticles

4-Dimethylaminopyridine (DMAP)-stabilized palladium nanoparticles with a mean diameter of 3.4 +/- 0.5 nm are prepared from the aqueous phase reduction of Na2PdCl4 using NaBH4 in the presence of DMAP. TEM and UV-vis spectroscopy characterization of the nanoparticle dispersion shows no obvious change in the nanoparticles several months after preparation. 1H NMR spectroscopy of the nanoparticles shows that the nanoparticle dispersion also contains a boron/DMAP complex and two palladium/DMAP complexes. One of the palladium complexes crystallizes out of the dispersion and is identified as Pd(DMAP)4(OH)2 by X-ray crystallography. Following extensive analysis, it is believed that the palladium/DMAP complexes are formed following the oxidation of the palladium nanoparticles. The prepared nanoparticle dispersion promotes selective hydrogen/deuterium (H/D) exchange on the carbon atoms alpha to the endocyclic nitrogen atom on the DMAP-stabilizing ligands through reaction with D2O. This activity is attributed to the presence of the nanoparticles rather than to the presence of the oxidized palladium/DMAP complexes.