Na_2Cu_5Shi_4·4H_2O配合物的合成、结构及性质研究

合成了Na2 Cu5Shi4 ·4H2 O配合物 ,经元素分析 ,IR ,UV ,NMR ,荧光及分子力学计算等表征了配合物的结构。 2D1 HNMR谱及磁矩等测定表明 ,配合物中水杨酰肟酸π电子分布有大的改变 ,最大吸收峰红移 2 5nm ,芳环d质子表现出烷烃质子性质 ;铜离子之间有强的磁相互作用 ,基态S为 1/2。

Na5SeV5O18·3H2O对K562细胞线粒体凋亡和NF-κB／IκBα信号转导途径的影响

通过MTT比色法和Westernblot法检测NasSeV5O18·3H2O的抗肿瘤活性及作用机理．结果表明，Na5seV5O18·3H2O（0．625-20mg·L^-1）能抑制K562细胞增殖（P〈0．05）；药物处理K562细胞24h，可使胞浆细胞色素C，IκBα含量明显增多，核内NF-κB含量减少．结果提示Na5SeV5O36·3H2O能体外抑制K562细胞增殖，其机理可能与线粒体凋亡和NF-κB／IκBα信号转导有关．

TiO_2/Li_4Ti_5O_(12)/Na_2Ti_6O_(13)复合催化剂的制备、表征及其光催化活性

采用反相微乳法,制备了TiO2/Li4Ti5O12/Na2Ti6O13复合催化剂,运用TG-DSC、XRD、SEM等分析方法对催化剂进行表征.在紫外光(λ=365 nm)照射下,以2,4-二氯苯酚(2,4-DCP)作为目标污染物,用P-25型TiO2作对照,研究了TiO2/Li4Ti5O12/Na2Ti6O13复合催化剂光催化降解2,4-DCP的特性.结果表明,制备的TiO2/Li4Ti5O12/Na2Ti6O13复合催化剂成带状纳米结构,其长度大于5μm,宽度约60 nm,厚度小于30 nm,结晶良好,分散性高,在紫外光照射下,50 min内对20 mg·L-1的2,4-DCP降解率达到了99.8%,表现出了比P-25型TiO2更高的光催化活性.

Na（NTO）（H2O）的制备、晶体结构及热力学性质研究

利用氢氧化钠溶液与NTO水溶液进行反应制备了标题化合物并培养出单晶.通过X射线单晶结构分析法测定分子结构和晶体结构,其分子式可表示为Na(NTO)(H2O),晶体属单斜晶系,P21/c空间群.晶体学参数为:a=0.6303(1)nm,b=0.8285(1)nm,c=1.1574(2)nm,β=103.85(1)°,V=0.5868(2)nm3,Dc=1.925g/cm3,Z=4,F(000)=344,μ=0.238 mm-1,R=0.0259.通过Na(NTO)(H2O)在水中溶解焓的测定,算得其标准生成焓、晶格焓和晶格能.

负载Cr_2O_3的H_2Ti_2O_5·H_2O纳米管的制备及其作为锂离子电池正极材料的电化学性能

限制纳米电极材料倍率性能的一个重要因素是,在大电流下充放电时,纳米结构可能坍塌,造成容量迅速衰减.通过异价离子的掺杂或第二相的负载有可能弥补纳米材料的这一缺陷.本文以含有Cr2O3的锐钛矿TiO2为原料,通过超声化学-水热法,制备了负载Cr2O3的H2Ti2O5·H2O纳米管.采用X射线衍射(XRD)和透射电镜(TEM)对制得的H2Ti2O5·H2O/Cr2O3纳米管的晶体结构和微观形貌进行了表征和分析.恒流充放电测试显示,H2Ti2O5·H2O/Cr2O3(5%(w,质量分数))纳米管作为锂离子电池阳极材料具有优异的循环稳定性及倍率性能.在150mA·g-1的电流密度下,H2Ti2O5·H2O/Cr2O3纳米管的首次放电容量达到288mAh·g-1;120次循环后,充放电容量仍保持在145mAh·g-1.在1500mA·g-1的电流密度下,首次放电容量为178mAh·g-1;600次循环后,充放电容量保持在80mAh·g-1以上;继续在150mA·g-1电流密度下充放电30个循环,充放电容量达到155mAh·g-1,显示出充放电容量的可回复性.循环伏安测试结果表明,H2Ti2O5·H2O/Cr2O3纳米管的充放电过程由法拉第赝电容反应控制.该一维纳米结构在锂离子电池和非对称电容器领域显示出良好的应用前景.

Ti/SnO_2-Sb_2O_5/PbO_2阳极电化学氧化降解咪草烟及其过程监测

Methodology for the electrochemical decomposition of imazethapyr using Ti/SnO2-Sb2O5/PbO2 anode in Na2SO4 medium is suggested in this paper. The electrolysis reaction conditions were optimized. The process of electrochemical decomposition was monitored by ultra-violet spectrophotometry and CODCr method. The electrochemical decomposition mechanism of imazethapyr was studied primarily by UV-VIS spectrophotometry. The effectiveness of the electrochemical pretreatment was proved by the comparative aerobic biological treatment test based on the activated sludge process.

电解液中添加La（NO3）3·6H2O及Na5P3O10对ZAlSi12表面微弧氧化层特性的影响

在硅酸盐电解液体系下对ZAlSi12铝合金进行微弧氧化,研究电解液中不同的添加剂对陶瓷膜形成过程及膜层特性的影响,采用SEM、XRD、EDS等分析手段分析陶瓷层的表面形貌、相组成及成分,同时测试了膜层的厚度。结果显示,加入La(NO3)3·6H2O后,膜层增厚,膜层的基本组成相仍为α-Al2O3和γ-Al2O3,且La(NO3)3·6H2O及Na5P3O10·6H2O的加入使两相的相对含量增加,能谱分析显示La元素及P元素也进入到膜层中,说明其不仅影响了烧结过程,还参与了氧化反应。

AQUEOUS PHASE SYNTHESIS OF(RC_5H_4)_2Ti(O_2CC_6H_4X)_2

Nine complexes(RC_5H_4)_2Ti(O_2CC_6H_4X)_2(R=H,CH_3;X=H,o-Cl,o-OH, o-NH_2,o-NHPh)have been conveniently prepared by the reaction of (RC_5H_4)_2TiCl_2 with 2 equiv.sodium salts of corresponding carboxylic acid in aqueous solution containing acetylacetone.The carboxylate ligands in the complexes coordinate to titanium atom in monodentate mode.

Na_2S_2O_3-CuSO_4-C_2H_5OH-H_2O四元系合成法制取CuOH及其性质的研究──关于在常温下或无苛性碱处理时Na_2S_2O_3跟CuSO_4反应生成CuOH成立之证明(Ⅰ)

通过提出合成CoOH的新方法，讨论了体系浓度、温度、催化剂对CuOH合成所具有明显的影响以及CuOH的某些物理性质和化学性质．采用Na2S2O3、CuSO4、C2H5OH、H2O为主要原料合成CuOH获得成功．

Na_2S_2O_3──CuSO_4──C_2H_5OH──H_2O合成法制取CuOH反应机理的研究(Ⅱ)

作者研究了Na2S2O3、CuSO4、C2H5OH、H2O四元素合成CuOH的反应机理．由碰撞理论推得Cu＋和CuOH的生成速率方程。实验结果表明，温度、浓度对区应速率都有一定的影响．

[Fe(CN)_5NO]^(2-)与S^(2-)反应产物的稳定性及其性质分析

用紫外-可见分光光度计对N a2S与N a2[Fe(CN)5NO]反应得到的紫色混合水溶液的稳定性进行跟踪检测,结果表明此紫色化合物极不稳定。进一步用显微熔点测定仪、红外光谱等仪器对该紫色混合液的分解产物—黄色针状晶体进行了鉴定,最终确定该晶体为黄血盐N a4[Fe(CN)6].3H2O。这一研究对N a2[Fe(CN)5NO]鉴定S2-的实验现象有更进一步的解释。

Synergistically enhancing cycleability and rate performance of sodium titanate nanowire anode via hydrogenation and carbon coating for advanced sodium ion batteries

Layered alkali-metal titanate materials are considered as attractive anodes for sodium ion batteries due to their favorable safety and low cost.However,their practical implementation faces major challenges of low electronic conductivity and inevitable volume variation during Na^(+)intercalation and de-intercalation,which are generally difficult to conquer by a single modification method.Herein,a synergistic ally enhancing strategy to promote the electrochemical performance of Na_(2)Ti_(2)O_(5)nanowire array anode via simultaneous hydrogenation and carbon coating is developed.Hydrogenation leads to partially reduced titanium;together with conductive carbon layer,it endows Na_(2)Ti_(2)O_(5)with fast electron transport and structural stability.The resulting H-Na_(2)Ti_(2)O_(5)@C anode exhibits enhanced rate capability(8.0C,165 mAh·g^(-1))and stable cycle performance up to 1000 times in sodium-ion half-cells(the capacity of H-Na_(2)Ti_(2)O_(5)without carbon fades drastically after only 100 cycles).In addition,a newcoupling full cell is further designed with graphene hybridized high-voltage Na_(3)(VO_(0.5))_(2)(PO4)_(2)F_(2)as cathode,capable of delivering a high specific energy density of 212.1 Wh·kg^(-1)(based on the mass of both anode and cathode)and good rate and cycling stability.This work may offer inspiration for synergistic optimization of electrode materials for advanced electrochemical energy storage devices.

纳米管钛酸钠的组成分析

以NaOH与多晶粉末TiO2作用制备了纳米管.使用原子吸收分光光度法、紫外-可见吸收分光光度法和失重分析三种分析方法,确定了该纳米管材料的组成为Na2Ti2O4(OH)2.