2,2'-双氨基苯氧基二硫化物及其聚合物的合成研究

在不同的锂或锂离子二次电池正极材料中 ,新型的聚有机二硫化物有可能成为最有应用前景的电池正极材料之一 [1] ,Visco等 [2 ]首次提出利用二硫化物中双硫键的断裂与再接 (即电聚合与电解聚 )化学性能应用于锂二次电池的充放电 .目前 ,对有代表性的有机二硫化物 2 ,5 -二巯基 -1 ,3 ,4-噻二唑(DMc T)进行了大量的研究[3～ 5] ,最近又提出通过合成新的聚有机二硫化物来提高其电化学性能[6 ,7] .为了得到一种新型高电化学活性和高导电性的锂或锂离子二次电池正极材料 ,本文通过化学方法合成2 ,2 -双氨基苯氧基二硫化物 (DAPD)单体 ,并通…     

聚有机二硫化物储能材料的电化学性能研究

有机二硫化物及其聚合物是80年代末才发展起来的一种新型的储能材料，这种材料的分子结构中含有双硫键（－S－S－），基于其可逆的电解聚－电聚合过程（2S^-→/←S－S＋2e^-）而这种材料有一个很大的优点是可以按预定的方式控制其有机基团和分子结构以及通过共聚、共混来改变其物理、化学和电化学性能。本文将介绍这种物质的反应机理、有关动力学参数的测定、电化学行为、导电聚合物对这种材料的电催化作用等方面的研究情况。     

LB型Q态CdS复合膜构象有序性研究

报道了在较高膜压及高沉积速度下硬脂镉ＬＢ膜与Ｈ２Ｓ反应制备纳米有序的机分子／ＣｄＳ纳米粒子复合膜,该膜反应后仍能保持良好的－ＣＨ２－全反式排列,即形成纵向有机－无机复合超晶格材料。     

聚(2,2＇-二氨基苯氧基二硫化物)结构与性能研究

用动电位连续扫描法制备了聚（2，2'-二氨基苯氧基二硫化物）（PDAPO），通过FT-IR，FT-Raman，XPS等测试技术确证其结构。聚合物产物与其单体的循环伏安实验结果表明，由于PDAPO结构中支链聚苯胺的电催化作用和强供电子键-O-S-S-O-的作用，其氧化还原反应的可逆性优于其它同类的聚有机二硫化物。研究了聚合物的导电性能、热稳定性及表面状态。结果表明，PDAPO是一种新型高电活性的导电聚合物，可用作锂或锂二次电池的正极材料。     

醌—硫硫聚合物的合成及电化学性能的研究

聚有机二硫化物的电化学性质，受到与它共聚的有机基团的影响。为此，我们以对苯二甲醚为原料经氯甲基化，硝酸氧化，与二硫化钠缩合制得了醌－硫硫共聚物，并用循环伏安法研究了该种共聚物的电化学性质，讨论了有机基团对Ｓ－Ｓ－键电化学性质的影响，并组装成电池研究它的放电行为。     

锂离子电池有机硫化物电极材料*

有机硫化物电极材料是一类新型高比容量的储能材料,通过S-S键的可逆断裂与键合进行释能与储能,主要应用于锂离子电池的正极。该材料包括有机二硫化物、有机多硫化物和硫化聚合物等。本文综述了有机硫化物电极材料的研究现状,分析了各种材料的优势与不足,并展望了其发展趋势。如何提高现有材料的比容量并改善其循环性能是目前的研究重点。     

Triton X－100／C_（10）H_（21）OH／H_2O体系层状液晶中超微粒子材料CdS的合成

ＴｒｉｔｏｎＸ－１００／Ｃ_（１０）Ｈ_（２１）ＯＨ／Ｈ_２Ｏ体系层状液晶中超微粒子材料ＣｄＳ的合成沈明，郭荣，严鹏权，于卫里（扬州大学师范学院化学系扬州２２５００２）关键词超微粒子，层状液晶，表面活性剂，ＴｒｉｔｏｎＸ－１００，ＣｄＳ超微粒子是指粒径?..     

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。     

邻苯二酚作螯合剂合成全硅方钠石（Si—SOD）和全硅ZSM—5（S …

通过在两个合成分子筛的体系ＳｉＯ２－ＮａＯＨ－ＥＧ－Ｒ和ＳｉＯ２－ＴＰＡＢｒ－ＮａＯＨ－Ｈ２Ｏ－Ｒ（Ｒ：邻苯二酚,ＥＧ;乙二醇）中加入邻苯二酚获得了具有较大尺寸和完善形貌的分子筛单昌。＾２９Ｓｉ ＮＭＲ,ＩＲ和ＵＶ－Ｖｉｓ光谱表明,在反应混和物中有硅－邻苯二酚螯全物生成,这种硅的螯合物在形成分子筛大单昌过程中起到了缓释硅源的作用。     

Pt／H－Ga－Si杂原子分子筛催化剂上丙烷芳构化

考察了在具有Ｐｅｎｔａｓｉｌ孔道结构的Ｈ－Ｇａ－Ｓｉ与Ｐｔ／Ｈ－Ｇａ－Ｓｉ杂原子分子筛及ＨＺＳＭ－５分子筛催化剂上的丙烷芳构化。Ｐｔ／Ｈ－Ｇａ－Ｓｉ有较高催化活性和芳烃选择性，用ＸＲＤ、ＴＥＭ和ＴＰＲ等技术对催化剂进行了表征，讨论了Ｐｔ与Ｇａ的相互作用。Ｐｔ／Ｈ－Ｇａ－Ｓｉ为双功能催化剂，Ｐｔ促进烷烃脱氢成为烯烃，还能降低丙烷裂解活性，而且可稳定骨架Ｇａ，使其不易脱除；Ｇａ可以提高中间烯烃转变为芳烃的选择性。Ｈ－Ｇａ－Ｓｉ与ＨＺＳＭ－５上的丙烷芳构化机理不同。Ｈ－Ｇａ－Ｓｉ上为丙烷脱氢机理，Ｇａ脱去Ｈ＋形成活泼正碳离子，同时由于骨架Ｇａ与分子筛Ｂ酸位相邻，所以可提高芳烃选择性；ＨＺＳＭ－５上丙烷活化是经过裂化机理，再通过氢转移步骤形成芳烃。     

Metal-catalyzed organosulfur cathodes for rechargeable lithium batteries

Extensive studies were carried out to apply composite materials composed of polyaniline (PAn) and 2,5-dimercapto-1,3,4-thiadiazole (DMcT) to develop cathode materials which exhibit high energy densities. Previous results have established that composites of PAn and DMcT which are coated onto copper substrates exhibit greatly enhanced charge and discharge performance. It is shown that composite materials composed of DMcT, PAn, and Cu ion have the ability to be reversibly charged and discharged at ca. 260 A h per kg-cathode (ca. 830 W h per kg-cathode) for more than 80 cycles. These two results are explored in general in this contribution via investigation of the electron transfer reactions between the components using UV/Vis and investigation of the copper substrate/DMcT chemistry using electrochemical quartz crystal microbalance and phase modulated interferometric microscopy.     

Development of polymer‐based lithium secondary battery

Novel polymer composites based on polydisulfide compounds are developed as a high energy density cathode material for lithium rechargeable batteries. A polymer composite composed of 2,5‐dimercapto‐1,3,4‐thiadiazole (DMcT) and conducting polymer polyaniline (PAn) on a copper current collector provides high charge density exceeding 225Ah/kg‐cathode with average discharge voltage at 3.4V. The composite cathode showed excellent rate capability and cyclability (>500 cycles). Surface analysis and electrochemical studies indicate that a DMcT‐Cu complex plays an important role in the observed improvement of the battery performances with a copper current collector. Large increase in the charge density to 550Ah/kg‐cathode is achieved by adding elemental sulfur (S₈) to the DMcT/PAn composite cathode.     

Disulfide-polyaniline composite cathodes for rechargeable batteries with high energy density

A composite cathode was prepared from a solution containing 2,5-dimercapto-1,3,4-thiadiazole (DMcT) and polyaniline (PAn). The resulting cathode exhibits 80% of the theoretical capacity. Furthermore, an energy density of over 600 Wh/kg-cathode and a discharge voltage of 3.4 V are obtained, when it is coupled with a lithium anode. Additional advantages of the present cathode material over the conventional metal oxides are the ease in disposal by incineration, the low pollution and the low cost. Current capability of 137 A/kg-cathode is achieved by adding a polypyrrole derivative to the DMcT-PAn composite and coupling it with a copper current collector.     

2,5-二疏基-1,3,4-噻二唑/聚邻甲基苯胺复合电极的电化学性能

有机二硫化合物;二疏基噻二唑;锂电池;2;5-二疏基-1;3;4-噻二唑/聚邻甲基苯胺复合电极的电化学性能     

Anthracene based organodisulfide positive active materials for lithium secondary battery

From facile preparation method and available low-cost raw materials, we have synthesized a novel kind of organodisulfide cathode materials based on anthracene for lithium secondary batteries – anthra[1^′,9^′,8^′-b,c,d,e][4^′,10^′,5^′-b^′,c^′,d^′,e^′]bis-[1,6,6a(6a-S^IV) trithia]pentalene (ABTH) and its homopolymer (PABTH), investigated the application of the organodisulfides to positive active material for lithium secondary batteries. The organodisulfides were characterized by FT-IR, XPS, and elemental analysis. The cyclic voltammetry tests reveal that the redox reaction of the ABTHs was processed in two steps. The experimental results showed that the polymer has the specific capacity of 300 mAh/g at second cycle and 250 mAh/g at the fifth cycle.     

聚苯胺对2,5—二巯基—1,3,4—噻二唑氧化还原反应的电化学？…

研究了聚苯胺（ＰＡn）膜电极在２,５－二巯基－１,３,４－噻二唑（ＤＭcＴ）溶液中电化学处理或浸泡后的循环伏安（ＣＶ）曲线的变化规律。实验结果表明,ＰＡn膜电极在 ＤＭcＴ溶液中进行电化学处理或浸泡过程可使ＤＭcＴ进入ＰＡn膜内部与ＰＡn形成复合物。ＰＡn对ＤＭcＴ的电化学催化作用可能和二者之间形成的电子给体－受体复合物有关。该复合物的电何尝氧化还原特性不同于ＰＡn对ＤＭcＴ的电化学催化作用可能和得之间形成的     

Solvent dependent dimercaptothiadiazole monolayers on gold electrode for the simultaneous determination of uric acid and ascorbic acid

Dimercaptothiadiazole compound, 2,5-dimercapto-1,3,4-thiadiazole (DMcT) forms ‘thin’ monolayers on Au electrode when it was adsorbed from methanol, ethanol or DMSO solutions while it forms ‘thick’ layers on Au electrode from an aqueous solution under identical experimental conditions. Thick DMcT layers formed from aqueous solution effectively blocks the redox reaction of couple in contrast to thin DMcT monolayers. The monolayer thickness did not vary when structurally related DMcT compounds, 5-methyl-1,3,4-thiadiazole-2-thiol or 5-amino-1,3,4-thiadiazole-2-thiol was adsorbed from aqueous and non-aqueous solutions. This indicates that the presence of two thiol groups in DMcT plays a crucial role in the formation of thick and thin DMcT layers on Au electrode when it was adsorbed from aqueous and non-aqueous solutions. Methanol, ethanol, or DMSO solution of DMcT is considered as strong acid because these solvents are able to deprotonate DMcT into DMcT⁻ and thus thin monolayers formed on Au electrode. The deprotonating ability of these solvents was further verified from the observed absorption spectrum characteristic of DMcT⁻ species. On the other hand, an aqueous solution of DMcT is less acidic due to weak deprotonation of DMcT by water and thus DMcT forms thick layer on Au electrode. Interestingly, thin DMcT monolayers formed from non-aqueous solvents separates the voltammetric signals of uric acid and ascorbic acid while thick DMcT layers formed from aqueous solution fails to separate them.     

用于锂离子电池正极材料的分级孔碳/2,5-二巯基-1,3,4-噻二唑/聚噻吩三元复合物

采用酚醛树脂为碳源, 纳米碳酸钙为二次成孔剂, 通过煅烧、刻蚀、KOH活化等工艺制备出活化分级孔碳(aHPC). 在此基础上, 以aHPC为模板, 通过溶液浸渍制得活化分级孔碳/2,5-二巯基-1,3,4-噻二唑(aHPC/DMcT)复合物, 然后运用氧化聚合法将聚(3,4-乙烯二氧噻吩)—聚苯乙烯磺酸(PEDOT-PSS)包覆在其表面制备出aHPC/DMcT/PEDOT-PSS复合物. 并运用傅里叶变换红外(FTIR)光谱、X射线衍射(XRD)、场发射扫描电镜(FESEM)、透射电镜(TEM)和电化学测试等手段对所得复合材料的结构、形貌及电化学性能进行表征. 结果显示, KOH活化后, aHPC孔道内的官能基团含量增加了, 使得DMcT的负载量增大(52%), 且DMcT几乎全部进入到aHPC孔道内. aHPC/DMcT复合物的首次放电容量为236 mAh·g^-1, 循环20次后放电比容量仅为65mAh·g^-1. 而aHPC/DMcT/PEDOT-PSS复合物的表面包覆一层PEDOT-PSS导电薄膜, 其首次放电容量高达281 mAh·g^-1, 20次后的放电比容量为138 mAh·g^-1,容量保持率达49.1%.     

Poly(2,5-dimercapto-1,3,4-thiadiazole) as a cathode for rechargeable lithium batteries with dramatically improved performance

Organosulfur compounds with multiple thiol groups are promising for high gravimetric energy density electrochemical energy storage. We have synthesized a poly(2,5-dimercapto-1,3,4-thiadiazole) (PDMcT)/poly(3,4-ethylenedioxythiophene) (PEDOT) composite cathode for lithium-ion batteries with a new method and investigated its electrochemical behavior by charge/discharge cycles and cyclic voltammetry (CV) in an ether-based electrolyte. Based on a comparison of the electrochemical performance with a carbonate-based electrolyte, we found a much higher discharge capacity, but also a very attractive cycling performance of PDMcT by using a tetra(ethylene glycol) dimethyl ether (TEGDME)-based electrolyte. The first discharge capacity of the as-synthesized PDMcT/PEDOT composite approached 210 mAh g(-1) in the TEGDME-based electrolyte. CV results clearly show that the redox reactions of PDMcT are highly reversible in this TEGDME-based electrolyte. The reversible capacity remained around 120 mAh g(-1) after 20 charge/discharge cycles. With improved cycling performance and very low cost, PDMcT could become a very promising cathode material when combined with a TEGDME-based electrolyte. The poor capacity in the carbonate-based electrolyte is a consequence of the irreversible reaction of the DMcT monomer and dimer with the solvent, emphasizing the importance of electrolyte chemistry when studying molecular-based battery materials.     

Poly(2,5‐dimercapto‐1,3,4‐thiadiazole) as a Cathode for Rechargeable Lithium Batteries with Dramatically Improved Performance

Organosulfur compounds with multiple thiol groups are promising for high gravimetric energy density electrochemical energy storage. We have synthesized a poly(2,5‐dimercapto‐1,3,4‐thiadiazole) (PDMcT)/poly(3,4‐ethylenedioxythiophene) (PEDOT) composite cathode for lithium‐ion batteries with a new method and investigated its electrochemical behavior by charge/discharge cycles and cyclic voltammetry (CV) in an ether‐based electrolyte. Based on a comparison of the electrochemical performance with a carbonate‐based electrolyte, we found a much higher discharge capacity, but also a very attractive cycling performance of PDMcT by using a tetra(ethylene glycol) dimethyl ether (TEGDME)‐based electrolyte. The first discharge capacity of the as‐synthesized PDMcT/PEDOT composite approached 210 mAh g^?1 in the TEGDME‐based electrolyte. CV results clearly show that the redox reactions of PDMcT are highly reversible in this TEGDME‐based electrolyte. The reversible capacity remained around 120 mAh g^?1 after 20 charge/discharge cycles. With improved cycling performance and very low cost, PDMcT could become a very promising cathode material when combined with a TEGDME‐based electrolyte. The poor capacity in the carbonate‐based electrolyte is a consequence of the irreversible reaction of the DMcT monomer and dimer with the solvent, emphasizing the importance of electrolyte chemistry when studying molecular‐based battery materials.