氮化硅陶瓷前驱体研究进展

聚硅氮烷可用作高温裂解法制备氮化硅陶瓷的前驱体。本文概括了近年来聚硅氮烷前驱体的研究及发展状况,总结了聚氮烷前驱体在合成,应用用以及裂解转化为陶瓷机理方面的研究进展。     

环硅氮烷的合成与应用研究进展(1)——环二硅氮烷

环二硅氮烷是有机硅氮化合物中结构与性能比较特殊的一类化合物,在材料化学及配位化学领域有重要的潜在应用前景.综述了近年来环二硅氮烷的合成方法与应用研究进展.在合成方面,主要分为3条路线,分别由环三硅氮烷锂盐、取代硅胺及六氯化二硅为起始物.在应用领域,介绍了环二硅氮烷的离子开环聚合、等离子聚合、与其它单体的共聚、水解和金属配合物的制备及其在陶瓷、粘合剂和预想的催化剂上的应用.     

聚硼硅氮烷陶瓷前驱体分子结构设计和合成*

聚硼硅氮烷是制备高性能硅硼 碳氮（SiBCN）复相陶瓷的主要聚合物前驱体,在耐高温、抗氧化高性能陶瓷领域中具有重要的研究价值。本文分4个方面,即基于硼吖嗪的聚硼硅氮烷、侧基含有环硼氮烷或单硼烷的聚硼硅氮烷、基于多官能硼烷构筑的聚硅氮烷和含硼聚硅基碳化二亚胺,从聚硼硅氮烷分子结构设计、改性、合成及在多维尺寸材料中初步应用的角度综述了该领域国内外研究的新进展,指出了聚硼硅氮烷陶瓷前驱体设计合成研究发展中值得关注的新方向。     

胺源对“一锅法”合成聚硼硅氮烷结构及性能的影响

以六甲基二硅氮烷(MM^N)、四甲基二乙烯基二硅氮烷(MM^NVi)和四甲基二硅氮烷(MM^NH) 3种不同结构的二硅氮烷为胺源,通过与氯硅烷和三氯化硼反应,制备出具有不同封端结构的聚硼硅氮烷.其中,以MM^N、MM^NVi为胺源可获得液态产物;以MM^NH为胺源时,因合成过程中发生活性基团间的过度交联导致产物凝胶.采用核磁共振波谱仪、红外光谱仪对液态前驱体聚合物及其热解产物的结构进行了表征.研究结果表明：通过“一锅法”制备的液态聚硼硅氮烷主链具有较多的支化和环状结构,随着封端结构中乙烯基含量的增加,所得前驱体的固化温度降低,固化反应活化能降低.与以MM^N为胺源和封端剂合成的聚硼硅氮烷相比,以MM^NVi为胺源所得前驱体固化前后陶瓷产率分别提高了14.9%及8.1%.并且,通过改变胺源的种类和比例可以调节热解产物的元素组成,合成的液态前驱体聚合物热解所得SiBCN陶瓷结晶温度高于1700℃.     

基于环硼氮烷的高陶瓷产率SiBCN先驱体的合成与性能

聚合物先驱体转化法作为制备SiBCN陶瓷及其复合材料的重要途径,具有成型温度低、产物结构和组成可控等优点.设计合成合适的聚合物先驱体是提高陶瓷产率和性能的关键因素之一,本文采用三氯环硼氮烷(TCB)与乙炔基氯化镁进行反应,合成了乙炔基环硼氮烷,进而与二氯硅烷和二氯甲基乙烯基硅烷进行共氨解反应,制备了聚硼硅氮烷先驱体(PBSZ)并进行了高温裂解.采用综合热分析(TG-DSG)对其陶瓷化过程进行了分析,并采用XRD和SEM对陶瓷化产物的结构进行了表征.PBSZ在室温下是液态,易溶于二氯甲烷和氯仿等溶剂,可加工性优良.基于PBSZ先驱体的SiBCN陶瓷产率超过80%;陶瓷化产物在1400℃以下为无定形状态,在1500℃可形成由α-Si3N4,β-Si3N4,h-BN和SiO2晶体结构组成的陶瓷;陶瓷产物表面致密平整且具有优异的热稳定性和氧化性能,表明聚硼硅氮烷(PBSZ)有望成为高陶瓷产率和高性能陶瓷的重要先驱体.     

聚硅氮烷在氨气中的裂解研究

聚硅氮烷在氨气中的裂解研究胡海峰陈朝辉冯春祥张长瑞宋永才（国防科技大学五系长沙４１００７３）关键词聚硅氮烷，氨气气氛，裂解机理先驱体转化法是制备陶瓷的一种独特方法，但裂解产物往往偏离化学稳定相组成，尤其是硅氮烷裂解后氮含量不足影响了材料的高温性能．...     

紫外光引发硅氢加成反应制备超支化聚碳硅氮烷

在二乙酰丙酮铂存在下, 以紫外光引发AB4型单体双(N,N-二烯丙基胺基)甲基硅烷发生硅氢加成反应, 制备了超支化聚碳硅氮烷. 聚合产物通过FTIR, 1H NMR, 13C NMR和29Si NMR谱和体积排除色谱/激光光散射联用技术进行表征. 与常规加热条件下Karstedt's催化剂催化的硅氢加成聚合相比, 光引发聚合的反应速度快. 波谱分析表明, 聚合过程中以α位硅氢加成反应为主. 光引发聚合制备的超支化聚碳硅氮烷支化度(DB)和平均支化数(ANB)分别为0.46和0.53, 与理论值相近. 其重均分子量为12500 g/mol, 分子量分布系数为2.1, Mark-Houwink方程指数α为0.44, 与热聚合制备的超支化聚碳硅氮烷的参数相近.     

新型氮化硼陶瓷纤维先驱体——含硅聚硼氮烷的合成与表征

以三氯化硼、六甲基二硅氮烷为起始原料, 采用一步法合成了一种新型含硅氮化硼陶瓷纤维先驱体——含硅聚硼氮烷. 该法合成工艺简单, 且合成收率约为87%(质量分数). 采用元素分析、傅立叶红外光谱、核磁共振波谱、热机械分析、动态流变分析等对含硅聚硼氮烷的组成、结构和性能进行了表征. 结果表明, N—B为含硅聚硼氮烷先驱体的骨架结构, 其中, B, N主要以硼氮六环形式存在, 而Si则以Si—CH₃, Si—N形式存在. 该先驱体软化点为110 ℃, 具有优良的成型性, 在190 ℃的N₂气氛中可纺丝得到20～25 μm的有机纤维.     

超支化聚碳硅氮烷的合成与表征

聚碳硅氮烷是一种新型含硅有机金属聚合物,其主链由硅氮碳连接而成,侧链为有机基团;与其它含硅聚合物(聚硅氮烷、聚碳硅烷等)类似,聚碳硅氮烷适于用做力学性能极佳且耐高温氧化的氮化硅(Si3N4)和氮化硅/碳化硅(Si3N4/SiC)复相陶瓷的前驱体.[1]超支化聚合物具有溶解性好、粘度低     

八苯基环二硅氮烷的新合成方法

本文报告了制备1,3－二氯－1,1,3,3－四苯基二硅氮烷（DCTPS）的新方法,此法不仅产率较高,而且产物易于分离纯化。此外,首次采用DCTPS与BuLi反应制备了N,N′－双（二苯基氯硅基）四苯基环二硅氮烷（BCPTPC）,并对其水解反应进行了详细研究,对水解产物进行了表征。     

锂离子电池正极材料锂镍氧化物研究新进展

锂镍氧化物是目前高容量大功率锂离子电池正极材料的主要候选材料之一 .本文详细介绍了锂镍氧化物作为锂离子电池正极材料的实用化困难与其结构的内在联系 ,以及解决这些困难所进行的合成方法和掺杂改性研究的概况 .探索新的合成方法以及多组分掺杂改性应是今后锂镍氧化物的研究方向     

磁性聚合物微球研究进展

磁性聚合物微球作为一种新型功能材料,在许多领域尤其是生物医药、生物工程等方面具有广阔的应用前景。本文综述了近年来磁性聚合物微球的制备及应用等方面的最新进展。     

RNA synthesis via dimer and trimer phosphoramidite block coupling

The solid-phase synthesis of oligoribonucleotides using dimer and trimer phosphoramidite blocks is described. This method significantly reduces the total number of steps required in the synthesis of a target RNA sequence, provides more material, and simplifies separation of the product from shorter failure sequences. The procedure is illustrated by the synthesis of UpU, ApA, and UpUpU phosphoramidite blocks and their use in the rapid synthesis of oligoribonucleotides on a solid support. Dimer and trimer amidite blocks will likely find use in the large scale solution (or solid)-phase synthesis of siRNA drugs.     

Synthesis of C(3) benzofuran-derived bisaryl quaternary centers: approaches to diazonamide A

[reaction: see text] Two complementary strategies for the synthesis of the diazonamide A bisaryl quaternary center are described. The first strategy relies upon an extremely facile tandem cyclopropanation/ring-opening sequence, which has proven amenable to chiral catalysis to provide enantioenriched material. The second strategy relies upon a more concise alkylation route ideal for material advancement.     

Remote Synthesis of Layered Double Hydroxide Nanosheets Through the Automatic Chemical Robot

As a family of two-dimensional functional materials, layered double hydroxides(LDHs) have the characteristics of adjustable lamellar element type and proportion, variable interlamellar anion, controllable particle size and thickness, providing a robust platform for photo/electro/thermal-catalysis. With the continuous progress of materials science, the synthesis of LDHs is becoming more and more refined. Herein, to achieve the fine preparation of LDHs materials, especailly for the no-chemical/material researchers, we successfully assembled the automatic synthesis device and wrote corresponding computer software to control this device, and the automatic synthesis of bulk and monolayer LDHs nanosheets on a laboratory scale can be realized. This work paves a new labor-saving way for the fine synthesis of LDHs nanostructures, further improving the development of LDHs-based materials.     

脂环族聚酰亚胺及其液晶取向膜材料

综述了近年来在脂环族聚酰亚胺领域内的研究进展,从单体的合成方法和分类以及脂环族聚酰亚胺的合成方法和实际应用等几方面系统阐述了该领域的研究进展,并着重讨论了其作为液晶显示器取向膜材料中的应用。     

Sequential Transformations in Organic Chemistry: A Synthetic Strategy with a Future

Organic-chemical synthesis has always fascinated chemists and will not lose its importance in the future. It is a truism that all chemists—and others too—are dependent on the synthesis of those compounds with which they want to work. As a result, organic-chemical synthesis today is more than ever before the cutting edge of organic chemistry, biology, biochemistry, medicine, physics, and material science. Synthesis is also the basis of the chemical industry. For the passionate synthetic chemist, however, synthesis is much more than just a method for obtaining compounds; it is the expression of his creativity, intelligence, ability, and also his perseverance.     

Combustion synthesis and characterization of nanocrystalline WO3

The energy payback time associated with the semiconductor active material is an important parameter in a photovoltaic solar cell device. Thus lowering the energy requirements for the semiconductor synthesis step or making it more energy-efficient is critical toward making the overall device economics more competitive relative to other nonpolluting energy options. In this communication, combustion synthesis is demonstrated to be a versatile and energy-efficient method for preparing inorganic oxide semiconductors such as tungsten trioxide (WO3) for photovoltaic or photocatalytic solar energy conversion. The energy efficiency of combustion synthesis accrues from the fact that high process temperatures are self-sustained by the exothermicity of the combustion process, and the only external thermal energy input needed is for dehydration of the fuel/oxidizer precursor mixture and bringing it to ignition. Importantly, we show that, in this approach, it is also possible to tune the optical characteristics of the oxide semiconductor (i.e., shift its response toward the visible range of the electromagnetic spectrum) in situ by doping the host semiconductor during the formative stage itself. As a bonus, the resultant material shows enhanced surface properties such as markedly improved organic dye uptake relative to benchmark samples obtained from commercial sources. Finally, this synthesis approach requires only very simple equipment, a feature that it shares with other "mild" inorganic semiconductor synthesis routes such as sol-gel chemistry, chemical bath deposition, and electrodeposition. The present study constitutes the first use of combustion synthesis for preparing WO3 powder comprising nanosized particles.     

二氧化碳和甲醇直接合成碳酸二甲酯的研究进展

碳酸二甲酯是一种重要的绿色化工原料,二氧化碳和甲醇直接合成碳酸二甲酯是一种绿色合成方法.本文介绍了近年来此方法的催化剂及其催化机理研究的进展,讨论了不同催化体系设计的理论基础和催化剂的作用机理,并对助催化剂和吸水剂以及反应条件对催化剂活性和选择性的影响进行了评述.     

可见光促进的偕二氟烯烃制备与应用研究进展

偕二氟烯烃化合物在医药、材料、精细化工等领域具有广泛的应用,同时也是一类非常重要的用于制备各类复杂的有机氟化合物的有机合成中间体.可见光催化反应具有条件温和、绿色清洁等特点,已经成为有机化学中非常重要的合成手段之一.本文综述了近年来可见光促进的偕二氟烯烃化合物的制备及其在有机合成化学中的应用.