新型无表面活性剂微乳液体系：乙醇/呋喃甲醛/水

通常, 微乳液一般由四个组分构成：水相、油相、表面活性剂和助表面活性剂。本文报道了一种不含表面活性剂的微乳液体系(简称SFME),由呋喃甲醛(油相),水和乙醇三组分构成,不含传统的表面活性剂。对其相行为进行了研究,发现存在一个单相微乳液区和一个两相平衡区。采用电导率法和冷冻蚀刻电镜(FF-TEM)考察了单相区域中微乳液的微结构,结果表明可分为油包水(O/W)、双连续(BC)和水包油(W/O)三个区域。液滴直径介于30~80nm。     

无表面活性剂微乳液体系：N,N－二甲基甲酰胺/呋喃甲醛/水

通常微乳液一般由四个组分构成：水相、油相、表面活性剂和助表面活性剂。本文报道了一种不含表面活性剂的微乳液体系(简称SFME),由呋喃甲醛(油相),水和N,N－二甲基甲酰胺(DMF)三组分构成,不含传统的表面活性剂。对其相行为进行了研究,发现存在一个单相微乳液区和一个两相平衡区。采用电导率法和冷冻蚀刻电镜(FF-TEM)考察了单相区域中微乳液的微结构,结果表明可分为油包水(O/W)、双连续(BC)和水包油(W/O)三个区域。液滴直径介于40-70nm。     

影响反相微乳液导电性能的因素

分别以聚乙二醇辛基苯基醚(Triton X-100)或十六烷基三甲基溴化铵(CTAB)为表面活性剂, 与正己烷、正己醇和水构成反相微乳液. 研究了水相H+浓度、表面活性剂、助表面活性剂等对微乳液导电性能的影响. 结果表明, 增加水相H+浓度可大幅度提高反相微乳液的导电能力, 当H+浓度由1.0 mol•L-1增加到10 mol•L-1时, 微乳液的电导率可提高1~2个数量级. 当水相H+浓度为10 mol•L-1时, 微乳液的电导率随溶水量的增大而增大, 水油体积比为3:10时, 两种体系的电导率均达到3200 μS•cm-1. Triton X-100浓度对微乳液的电导率影响较大, 电导率随其浓度增加而增大；而CTAB浓度对微乳液电导率的影响较小, 电导率随其浓度增加略有减小；助表面活性剂正己醇使非离子型反相微乳液的电导率下降, 而使阳离子型反相微乳液的电导率先增大, 然后减小, 呈骆峰状变化.     

微乳液体系中溶剂热合成Co纳米纤维

纳米材料的小尺寸及大的表面积使其在光学、电学、磁学以及化学性质上与体相材料具有显著的差异 ,从而在催化、电子、光学、磁性存储和超导等多方面具有很大的应用前景 [1] .目前 ,已经开发出许多制备纳米颗粒的技术 ,如溅射法、共沉淀法、溶胶 -凝胶法、水热法和微乳液法等 .其中利用微乳液等两亲分子有序组合体进行化学反应制备纳米材料是近十几年发展起来的新方法 ,该方法由于具有实验装置简单、易于操作和粒度可控等优点而引起人们的重视 [2 ] .微乳液是一种高度分散的间隔化液体 ,水 (或油 )相在表面活性剂 (助表面活性剂 )的作用下以…     

阴离子型微乳液的电导行为及其溶液结构

根据电导测量,研究了属于W/O→双连续→O/W一类微乳液的十二烷基硫酸钠(SDS)/正丁醇/辛烷/水体系的溶液结构.并探讨了表面活性剂离子对微乳液导电行为的贡献,以及表面活性剂与助表面活性剂含量、油含量对微乳液溶液结构的影响.微乳液的导电行为在W/O子区域中主要是由于SDS阴离子和在O/W子区域中是由于Na离子的影响.在双连续区(IZ)中SDS阴离子和Na阳离子都能影响导电行为增加表面活性剂含量有助于形成O/W微乳液,而助表面活性剂和油含量都增加有助于于形成W/O微乳液.     

离子液体微乳液体系的应用研究

室温离子液体具有诸多优异的物理化学性质及功能,是一类备受关注的新型介质和材料,应用于诸多领域。特别是近年来,由离子液体参与形成的微乳液因其在生物、医药、催化以及材料制备等领域具有潜在的应用前景而备受关注。本文综述了近年来咪唑类离子液体作为极性、非极性和表面活性剂组分,分别取代微乳液体系中的水相、油相和表面活性剂相,形成的一系列新型的微乳液体系的研究进展,归纳了水、有机溶剂、高聚物、助表面活性剂、温度等因素对离子液体微乳液性质的影响。重点介绍了离子液体微乳液的热点应用,包括以离子液体微乳液液滴为模板合成纳米材料,离子液体微乳液作为酶反应的介质及其在有机反应等方面的研究进展。     

十二烷基硫酸钠中相微乳液的液晶结构

微乳液是指油、水、表面活性剂、助表面活性剂形成的各向同性的、光学透明或半透明的热力学稳定体系．中相微乳液是指富表面活性剂相与过剩水相、过剩油相形成的三相体系．中相微乳液既可增溶水,又可增溶油,且与过剩水相、油相超低的界面张力,因而在强化采油中引起人们...     

以非离子型表面活性剂形成微乳液的碳原子数相关性研究

由非离子型表面活性剂、助表面活性剂（醇）、水和油形成微乳液,用拟三角相图中微乳区的面积确定形成微乳液的最佳条件,实验证明,油的碳原子数加上醇的碳原子数等于表面活性剂的碳原子数对为微乳液形成最佳条件,也符合ＢＳＯ规律。     

阳离子表面活性剂中相微乳的形成和特性

自1943年SdriAn。等人山发现微乳液体系并予以命名以来，对微乳液研究不断深入·微乳液是由油、水、表面活性剂和助表面活性剂组成的各向同性、透明的、热力学稳定的分散体系，微乳液可分为单相微乳液和多相微乳液问．中相微乳液是多相微乳液中，与过剩盐水相和过剩油相达到三相平衡的Winsor皿型微乳液，它在三次采油、日用化工、微环境、酶催化等方面具有特殊重要的应用I‘，‘］．近年来对阴离子表面活性剂中相微乳液的形成和特性进行了较多研究［5。8］．但对阳离子表面活性剂中相微乳液的研究，目前尚未见报导，本文以澳代十四烷基毗…     

微乳液催化苯乙烯聚合反应

微乳液催化苯乙烯聚合反应１）郝京诚汪汉卿２）（中国科学院兰州化学物理研究所兰州７３００００）石元昌李干佐（山东大学胶体与界面化学研究所济南２５０１００）关键词微乳液催化苯乙烯聚合微乳液［１］是油、水、表面活性剂和助表面活性剂在适当比例下自发形成的热力...     

磷酸钐包覆对高电压镍锰酸锂正极材料电化学性能的影响

尖晶石型镍锰酸锂(LiNi_0.5Mn_1.5O₄)因制备成本低、 放电平台高及循环寿命长等优点, 越来越多地应用于大型储能设备、 能量转换设备、 动力汽车等领域. 然而LiNi_0.5Mn_1.5O₄在高电压(5 V)充电状态下电解液易分解, 从而导致比容量降低以及循环性能衰退. 针对以上问题, 采用水热法制备磷酸钐(SmPO₄)表面包覆改性LiNi_0.5Mn_1.5O₄正极材料, 研究了SmPO₄包覆量对LiNi_0.5Mn_1.5O₄材料电化学性能的影响. 结果表明, 当SmPO₄包覆量为0.5%(质量分数)时, 改性材料(LNMO@SP-0.5)的电化学性能最优, 在0.2C和5C倍率下的放电比容量分别为129.2和90.9 mA?h/g, 而未包覆的材料Pristine LNMO的放电比容量分别仅有114.2和77.7 mA?h/g. 在常温1C倍率下循环200次后, LNMO@SP-0.5的容量保持率为93.4%, 而Pristine LNMO的容量保持率仅为86.6%. 这归因于SmPO₄包覆能够有效缓解LiNi_0.5Mn_1.5O₄材料与电解液之间的副反应, 降低电极的极化程度和电荷转移电阻, 增加了Li⁺的扩散系数.     

水葫芦与神府煤共成浆性的研究

分别以甲基萘磺酸盐(MF)及改性碱木质素磺酸钠(B1)为分散剂,考查了水葫芦与神府煤的成浆性能。结果表明,当100 g煤中加入19.16 g的水葫芦时,以MF为分散剂,60%浓度水葫芦煤浆的表观黏度为1 154 mPa.s,Fe2(SO4)3改性水葫芦煤浆的表观黏度为999 mPa.s。以B1为分散剂,水葫芦煤浆的表观黏度略有提高。Fe2(SO4)3的加入减少了与水缔合的含氧官能团数量,增加了水葫芦中起降黏作用的自由水含量。水葫芦能有效的提高水煤浆的稳定性,使出现硬沉淀的时间从2 h延长到60 h,Fe2(SO4)3作用后的水葫芦可进一步提高水煤浆的稳定性,使其出现硬沉淀的时间延长到88 h以上。水葫芦中大量的亲水性含氧官能团以及纤维素等大分子是水煤浆稳定性提高的主要原因。     

Pd/Co3O4纳米颗粒负载于Al2O3纳米片高效催化甲烷燃烧

We report an efficient catalyst composed of ternary components prepared by inlaying Pd/Co₃O₄ nanoparticles in alkaline Al₂O₃ nanosheets for catalytic oxidation of methane. Pd/Co₃O₄ inlaid in alkaline Al₂O₃ exhibited a higher ability to break the C-H bond of methane than Pd/Co₃O₄ supported on SiO₂, ZrO₂, CeO₂, and acidic or neutral Al₂O₃. Our results show more oxygen vacancies and higher amounts of surface adsorbed oxygen on the surface of Pd/Co₃O₄/alkaline Al₂O₃ than on other catalysts, which is responsible for methane activation and conversion. Further, the Pd/Co₃O₄/alkaline Al₂O₃ catalyst can almost restore to its initial value in the absence of water when 5% (volume fraction) vapor water was cut off, although a decrease in activity occurred when water vapor was introduced to the reaction system. Even under a condition similar to the exhaust of a lean-burn natural gas engine, the catalytic performance of the Pd/Co₃O₄/alkaline Al₂O₃ catalyst is excellent, that is, methane could be completely converted when the sample temperature in the reaction atmosphere was ramped to 400℃.     

Synthesis and characterization of Na5[Co(CO)3(P{(CH2)nC6H4-P-SO3}3)2], n = 1, 2, 3, and 6. Novel zwitterion

The electron donating water soluble phosphines, P{(CH₂)nC₆H₄-p-SO₃Na}₃,n = 1, 2, 3 and 6, react rapidly with Co₂(CO)₈ under two phase reaction conditions to yield the disproportionation products, [Co(CO)₃(P{(CH₂)nC₆H₄-p-SO₃Na₃}₂] [Co(CO)₄]. Selective precipitation yields the formally zwitterionic complex anions as the sodium salt, [Co(CO)₃(P{(CH₂)nC₆H₄-p-SO₃} ₃)₂]⁵⁻. The anions can be used as precursors to water soluble cobalt hydroformylation catalysts under two phase and supported aqueous phase conditions. The tendency to form alcohol products is low with these complexes. The behavior of the catalysts is consistent with an active species that remains water soluble during the reaction and is not leached into the nonaqueous phase.     

In situ Carbon Modification of g-C3N4 from Urea co-Crystal with Enhanced Photocatalytic Activity Towards Degradation of Organic Dyes Under Visible Light

An in situ strategy was introduced for synthesizing carbon modified graphitic carbon nitride(g-C₃N₄) by using urea/4-aminobenzoic acid(PABA) co-crystal(PABA@Urea) as precursor materials. Via co-calcination of the PABA co-former and the urea in PABA@Urea co-crystals, C guest species were generated and compounded into g-C₃N₄ matrix in situ by replacing the lattice N of the carbon nitride and forming carbon dots onto its layer surface. The carbon modification dramatically enhanced visible-light harvesting and charge carrier separation. Therefore, visible light photo-catalytic oxidation of methylene blue(MB) pollution in water over the carbon modified g-C₃N₄(C/g-C₃N₄) was notably improved. Up to 99% of methylene blue(MB) was eliminated within 60 min by the optimal sample prepared from the PABA@Urea co-crystal with a PABA content of 0.1%(mass ratio), faster than the degradation rate over bare g-C₃N₄. The present study demonstrates a new way to boost up the photocatalysis performance of g-C₃N₄, which holds great potential concerning the degradation of organic dyes from water.     

Modelling of calcium sulphate solubility in concentrated multi-component sulphate solutions

The chemistry of several calcium sulphate systems was successfully modelled in multi-component acid-containing sulphate solutions using the mixed solvent electrolyte (MSE) model for calculating the mean activity coefficients of the electrolyte species. The modelling involved the fitting of binary mean activity, heat capacity and solubility data, as well as ternary solubility data. The developed model was shown to accurately predict the solubility of calcium sulphate from 25 to 95 °C in simulated zinc sulphate processing solutions containing MgSO₄, MnSO₄, Fe₂(SO₄)₃, Na₂SO₄, (NH₄)₂SO₄ and H₂SO₄. The addition of H₂SO₄ results in a significant increase in the calcium sulphate solubility compared to that in water. By increasing the acid concentration, gypsum, which is a metastable phase above 40 °C, dehydrates to anhydrite, and the conversion results in a decrease in the solubility of calcium sulphate. In ZnSO₄–H₂SO₄ solutions, it was found that increasing MgSO₄, Na₂SO₄, Fe₂(SO₄)₃ and (NH₄)₂SO₄ concentrations do not have a pronounced effect on the solubility of calcium sulphate. From a practical perspective, the model is valuable tool for assessing calcium sulphate solubilities over abroad temperature range and for dilute to concentrated multi-component solutions.     

微波辅助快速制备2D/1D ZnIn2S4/TiO2 S型异质结及其光催化制氢性能

The threat and global concern of energy crises have significantly increased over the last two decades. Because solar light and water are abundant on earth, photocatalytic hydrogen evolution through water splitting has been considered as a promising route to produce green energy. Therefore, semiconductor photocatalysts play a key role in transforming sunlight and water to hydrogen energy. To date, various photocatalysts have been studied. Among them, TiO₂ has been extensively investigated because of its non-toxicity, high chemical stability, controllable morphology, and high photocatalytic activity. In particular, 1D TiO₂ nanofibers (NFs) have attracted increasing attention as effective photocatalysts because of their unique 1D electron transfer pathway, high adsorption capacity, and high photoinduced electron–hole pair transfer capability. However, TiO₂ NFs are considered as an inefficient photocatalyst for the hydrogen evolution reaction (HER) because of their disadvantages such as a large band gap (~3.2 eV) and fast recombination of photoinduced electron–hole pairs. Therefore, the development of a high-performance TiO₂ NF photocatalyst is required for efficient solar light conversion. In recent years, several strategies have been explored to improve the photocatalytic activity of TiO₂ NFs, including coupling with narrow-bandgap semiconductors (such as ZnIn₂S₄). Recently, microwave (MW)-assisted synthesis has been considered as an important strategy for the preparation of photocatalyst semiconductors because of its low cost, environment-friendliness, simplicity, and high reaction rate. Herein, to overcome the above-mentioned limiting properties of TiO₂ NFs, we report a 2D/1D ZnIn₂S₄/TiO₂ S-scheme heterojunction synthesized through a microwave (MW)-assisted process. Herein, the 2D/1D ZnIn₂S₄/TiO₂ S-scheme heterojunction was constructed rapidly by using in situ 2D ZnIn₂S₄nanosheets decorated on 1D TiO₂ NFs. The loading of ZnIn₂S₄ nanoplates on the TiO₂ NFs could be easily controlled by adjusting the molar ratios of ZnIn₂S₄ precursors to TiO₂ NFs. The photocatalytic activity of the as-prepared samples for water splitting under simulated solar light irradiation was assessed. The experimental results showed that the photocatalytic performance of the ZnIn₂S₄/TiO₂ composites was significantly improved, and the obtained ZnIn₂S₄/TiO₂ composites showed increased optical absorption. Under optimal conditions, the highest HER rate of the ZT-0.5 (molar ratio of ZnIn₂S₄/TiO₂= 0.5) sample was 8774 μmol·g^-1·h^-1, which is considerably higher than those of pure TiO₂ NFs (3312 μmol·g^-1·h^-1) and ZnIn₂S₄nanoplates (3114 μmol·g^-1·h^-1) by factors of 2.7 and 2.8, respectively. Based on the experimental data and Mott-Schottky analysis, a possible mechanism for the formation of the S-scheme heterojunction between ZnIn₂S₄ and TiO₂ was proposed to interpret the enhanced HER activity of the ZnIn₂S₄/TiO₂heterojunctionphotocatalysts.      

NiMo(O)物相结构与电解水析氢反应活性的关联（英文）

在电催化析氢反应中,Ni Mo(O)催化剂在高电流密度下通常表现为极低的过电位。然而,该优异电催化性能的真正起源尚不明确。一个新的角度,即研究钼镍催化剂结构/性能演变的规律,能够帮助深入理解镍钼催化剂具有高活性的本质原因。基于此,本文详细阐述了含有结晶水的钼酸镍的脱水和氧化过程,在随后的还原处理中,该演变过程也被证实对于衍生不同的催化剂相结构具有重要作用。文中通过热重-差热分析以及程序升温氢气还原的方法探究电催化剂的特征相结构演变过程。同时,借助X射线衍射仪、拉曼光谱和高分辨透射电子显微镜分析确认催化剂物相。原位电化学X射线衍射分析提供了电催化剂在反应过程中的晶相结构。本文合成了具有不同主体相结构的钼镍催化剂：MoNi₄,β-NiMoO₄和α-NiMoO₄,它们的析氢反应活性具有显著差异。其中,β-NiMoO₄作为主体相结构的NiMoO₄-400air-H₂催化剂在碱性水还原反应中显现出最差的析氢性能;与之相比,α-NiMoO₄作为主...     

Ru3(CO)9(TPPTS)3催化的水/有机两相芳香硝基化合物CO选择性还原的研究

将水溶性膦/钌配合物Ru₃(CO)₉(TPPTS)₃(TPPTS:三苯基膦三-间磺酸钠)用于以CO为还原剂的水/有机两相芳香硝基化合物选择还原为芳胺的反应,发现相转移催化剂对反应有明显的促进作用,其中以添加十六烷基三甲基溴化铵(CTAB)的效果最好.以邻氯硝基苯为底物考察了相转移催化剂浓度、NaOH浓度、反应温度、压力等对反应转化率和选择性的影响.当反应条件为120℃,4MPa,3mol/LNaOH时,反应8h,邻氯硝基苯的转化率和邻氯苯胺的选择性均可达到99.9%.而且对含有羰基、氰基的芳香硝基化合物也有很高的活性和选择性.催化剂循环3次后,邻氯硝基苯的转化率和邻氯苯胺的收率仍可达到92%.     

应用水汽相变促进湿法脱硫净烟气中PM_(2.5)和SO_3酸雾脱除的研究

在石灰石-石膏法脱硫净烟气中分别采用添加适量蒸汽和湿空气方式建立PM_(2.5)和SO_3酸雾凝结长大所需的过饱和水汽环境,在测试分析湿法脱硫净烟气中PM_(2.5)及SO_3酸雾物性的基础上,考察了蒸汽及湿空气添加量、脱硫净烟气温度等的影响。结果表明,湿法脱硫净烟气中PM2.5除含有燃煤飞灰外,含Ca SO_4、Ca SO_3及未反应的Ca CO_3等组分;由于SO_3酸雾基本处于亚微米级粒径范围,湿法烟气脱硫(WFGD)系统对SO_3酸雾的脱除率仅为35%-55%;添加适量蒸汽及湿空气方式均可促进湿法脱硫净烟气中PM_(2.5)和SO_3酸雾脱除,最终排放浓度随蒸汽或湿空气添加量的增加而降低,其中,添加蒸汽方式适合于脱硫净烟气温度较低(≤50-55℃)的场合,在脱硫净烟气温度较高(≥55-60℃)时,利用添加湿空气方式替代添加蒸汽更具技术经济优势。