Co-coating effect of GdPO4 and carbon on LiFePO4 cathode surface for lithium ion batteries

The electronic conductivity enhanced has been extensively studied and reported in lithium iron phosph-ate (LiFePO₄). However, only few existing literatures are available for researchers to enhance simultaneously the ion and electronic conductivity of LiFePO₄. Herein, we disclose that the LiFePO₄ is co-coated with novel GdPO₄ and Carbon via a hydrothermal-assisted solid-phase method, contributing to particle size and dispersibility. What surprising is that the ionic and electronic conductivity of the material is significantly enhanced, and the interfacial side reaction is effectively inhibited between the materials and the electrolytes. The diverse proportions of the mixed coating (LiFePO₄/C&xGdPO₄ (x = 0, 1 wt%, 2 wt%, 3 wt%, 4 wt%)) are synthesized compared with bare LiFePO₄. The experimental results suggest that LiFePO₄/C&0.03GdPO₄ exhibits the most excellent electrochemical performance. There is discharge capacity of 158, 148.8, 141.6, 134.9, 121.8, 104.9, and 86.7mAh/g at 0.1, 0.2, 0.5, 1, 2, 5, and 10 C rates, respectively.     

新型着色材料——速溶色浆粉的测试与应用

介绍了通过初级颜料的润湿、研磨与分散、稳定处理技术,使助剂和树脂均匀地包裹在颜料表面,并通过特殊工艺制得水性和油性色浆粉,并赋予了很好的速溶性和分散性。     

改性纳米碳酸钙用于硅酮胶挤出性研究

采用碳化法合成纳米碳酸钙,在反应过程中,调整反应起始温度合成不同晶型大小的纳米碳酸钙。通过透射电镜（TEM）、激光粒度仪对碳酸钙的物相、形貌、粒度进行分析,将改性纳米碳酸钙应用于硅酮胶基料制备及挤出性研究,分析改性纳米碳酸钙的颗粒大小、分散性、流变性能及表面改性剂对挤出性的影响。结果表明：粒径介于50~90 nm,屈服值介于66.4~148.9 Pa,黏度介于0.5~0.75 mPa·s,硬脂酸钠与LH-2、LH-3两种包覆剂进行复配改性的纳米碳酸钙用于硅酮胶基料具有较好的挤出性能。     

粗纤度PVA纤维混凝土力学性能试验分析

将粗纤度聚乙烯醇(PVA)纤维加入混凝土中,采用搅拌试验方法分析PVA纤维在混凝土中的分散性;对比不同纤维体积分数下PVA纤维混凝土的坍落度分析其可施工性;对比不同纤维体积分数PVA纤维混凝土的抗压、抗弯拉及劈裂抗拉强度和破坏状态来探索其综合力学性能。试验结果表明:PVA纤维在混凝土搅拌过程中分布较均匀不易结团;相对素混凝土,PVA纤维混凝土的坍落度略有下降;抗压强度无明显提高,抗弯拉及劈裂抗拉强度随着纤维体积分数增加呈二次函数增大。     

衣康酸改性聚环氧琥珀酸的合成及其阻垢缓蚀性能的研究

目的为了拓宽聚环氧琥珀酸(PESA)的应用范围,合成了衣康酸改性聚环氧琥珀酸衍生物(IA-PESA),拟提高PESA的阻垢缓蚀性能。方法用顺酐合成环氧琥珀酸(ESA)和聚环氧琥珀酸(PESA),再利用ESA与衣康酸(IA)聚合制得IA-PESA,研究了IA-PESA的阻垢和缓蚀等综合性能。用FT-IR对PESA和IA-PESA进行表征。用黏度法测定了PESA和IA-PESA的分子量。结果在静态阻垢实验中,对CaCO_3阻垢率达到90%以上,对CaSO_4阻垢率高达95%,甚至100%。IA-PESA分散Fe(Ⅲ)和稳定Zn~(2+)性能明显好于PESA。在静态失重实验中,当IA-PESA与PESA的用量均为150 mg/L时,加IA-PESA的腐蚀速率明显小于加PESA的腐蚀速率。对钙垢和腐蚀试片的SEM研究表明,IA-PESA使致密度较高、晶格结构规整的CaCO_3和CaSO_4钙垢改变为致密度较低、疏松、形状不规整的晶型结构。IA-PESA使试片未发生均匀腐蚀和点蚀,表面光滑。结论在相同测试条件下,IA-PESA的阻垢、缓蚀、分散Fe(Ⅲ)和稳定锌性能都好于PESA,改变了设备表面钙垢的晶型结构,减少了垢下腐蚀,缓蚀作用明显。     

石墨烯在PAO基础油中的摩擦学性能

为了改善石墨烯在润滑油中的分散稳定性,利用一种高分子量丁二酰亚胺（分散剂A）辅助石墨烯分散于聚α-烯烃（PAO4）基础油中,采用紫外-可见分光光度法对其分散稳定性进行了监测,并使用UMT-3多功能摩擦试验仪和ContourGT-K型三维轮廓仪考察了石墨烯/PAO4分散液的摩擦磨损性能,利用扫描电子显微镜（SEM）、能谱仪（EDS）和X射线光电子能谱（XPS）对磨痕表面的形貌和元素组成进行定性和定量分析。结果表明：分散剂A可有效提高石墨烯在PAO4中的分散稳定性,加入分散剂A后,石墨烯/PAO4分散液静置一周后的相对浓度为0.667,是未加分散剂的分散液的7.8倍;石墨烯作为润滑油添加剂能显著提升摩擦磨损性能,添加0.8 mg/mL的石墨烯和质量分数为0.2%的分散剂A,跑合期从670 s缩短至250 s,磨损体积减少了55%。     

纳米金刚石膜的成核及生长特性研究

采用直流等离子体喷射化学气相沉积(DC arc pla sma jet)系统制备了纳米金刚石膜(NCD),研究了不同的金刚石成核剂溶液对NCD 膜的成核及生长的影响。研究表明,在成核剂溶液中添加二甲基亚砜(DMSO)后成核密度明显 得到提高,而 且制备的NCD膜晶粒分布均匀、致密。当金刚石粉体作为成核剂时,随着其粒径 的增大,NCD膜成核密度下降,晶粒的尺寸均匀性也变差,而粒径为5nm的金刚石纳米粒 子作为成核剂时,NCD膜晶粒间结合致密、颗粒分布均匀。最后,选择5nm的金刚石纳米 粒子和丙酮/DMSO配制的分散液作为成核剂配方,经过60min的生长 ,制备了粒径为50～70 nm的结晶性和品质良好的NCD膜,适用于高频声表面波(SAW)器件及各种光学窗口的研制。     

单壁碳纳米管在PSS水溶液中的分散

本文通过混酸氧化法制备羧基化单壁碳纳米管(SWNTs-COOH),以聚苯乙烯磺酸钠(PSS)为分散剂,通过磁力搅拌、超声处理,制备SWNTs-COOH-PSS分散液,运用傅里叶红外光谱、显微共聚焦激光拉曼、场发射扫描电子显微镜、透射电子显微镜、紫外-可见光吸收光谱对不同条件下的SWNTs分散液进行表征比较。结果表明:原料SWNTs通过本法成功修饰上羧基,制备的初始质量浓度为3g/L的SWNTs-COOH-PSS分散液,室温静置30天以上不发生絮凝。     

Co-processing as a tool to improve aqueous dispersibility of cellulose ethers

Cellulose ethers are important materials with numerous applications in pharmaceutical industry. They are widely employed as stabilizers and viscosity enhancers for dispersed systems, binders in granulation process and as film formers for tablets. These polymers, however, exhibit challenge during preparation of their aqueous dispersions. Rapid hydration of their surfaces causes formation of a gel that prevents water from reaching the inner core of the particle. Moreover, the surfaces of these particles become sticky, thus leading to agglomeration, eventually reducing their dispersion kinetics. Numerous procedures have been tested to improve dispersibility of cellulose ethers. These include the use of cross-linking agents, alteration in the synthesis process, adjustment of water content of cellulose ether, modification by attaching hydrophobic substituents and co-processing using various excipients. Among these, co-processing has provided the most encouraging results. This review focuses on the molecular mechanisms responsible for the poor dispersibility of cellulose ethers and the role of co-processing technologies in overcoming the challenge. An attempt has been made to highlight various co-processing techniques and specific role of excipients used for co-processing.     

纳米SiO2和MgAl-SDBS-LDHs在聚丙烯中的协同分散及协效阻燃性能研究

以有机改性纳米SiO2和MgAl-SDBS-LDH为填料,采用熔融共混法制备PP/MgAl-SDBS-LDHs、PP/MgAl-SDBS-LDHs/SiO2复合材料。采用XRD、TGA、氧指数仪、水平垂直燃烧仪和锥形量热仪等方法,探讨纳米SiO2、MgAl-SDBS-LDHs在聚丙烯中的协同分散及协效阻燃性能。结果表明:相比PP/MgAl-SDBS-LDHs,PP/MgAl-SDBS-LDHs/SiO2复合材料体系的分散性得到明显改善。PP/5%MgAl-SDBS-LDHs/10%SiO2复合材料的初始分解温度较纯PP升高62℃,残留量达到11.18%。样品达到UL-94水平燃烧测试标准,极限氧指数(LOI)提高3.8,平均质量损失速率(AMLR)下降1.8g/(m2·s),生烟总量(TSP)增加4.7m2,热释放速率峰值(PHRR)下降41%。有机改性纳米SiO2改善了MgAl-SDBS-LDHs在聚丙烯中的分散性并提高了复合材料的阻燃性能。