多壁碳纳米管对沙林的敏感性研究

自碳纳米管被发现以来,由于其具有许多独特的电学、磁学、力学和气敏特性而引起了人们广泛的关注,在结构增强、纳米电子器件、场发射、储氢、传感器等众多领域具有非常广阔的应用前景,成为当前研究的热点之一[1,2].近年来,随着碳纳米管在传感器特别是气体检测领域研究的不断深入,碳纳米管为敏感材料的传感器已成功应用于对O2、NO2、NH3、H2等气体的检测研究[3],其中对NO2的检测可达到10×10-9(φ),但尚未见碳纳米管用于毒剂检测的报道.本文以碳纳米管作为石英晶体微天平膜材料,研究了碳纳米管的化学修饰方法及其对检测沙林的影响,结果表明经强酸加热氧化的碳纳米管对沙林响应大、解吸快、重复性好,可以作为传感器检测沙林的膜材料.该研究为碳纳米管在化学毒剂中的应用奠定了基础.     

硫化锌纳米粒子的乳液合成

纳米材料被人们认为是新型的功能材料^[1]。作为过渡金属硫化物,硫化锌（ZnS)材料显示出许多特异光电性能,在许多领域有着广泛的应用^[2],因而一直被应用和研究。     

生物蛋清蛋白模板合成海绵状大孔无机氧化物

多孔无机材料因可在微加工,催化,生物分离,电子器件的矿化和色谱载体等方面的广泛应用而引起人们极大的兴趣^[1-9],模板技术是制备孔材料最有效的工具之一,以表面活性剂和嵌段共聚物作为模板剂可以合成出结构多样,孔径均一,有序度高的介孔分子筛（2－50nm),大孔无机材料（＞50nm)通常采用以高分子微球和微乳液作模板的方法来合成（^[10],最近,我们利用浓度极高的;盐溶液和聚苯乙烯球作为模板,合成了3D海绵状大孔和介孔复合的氧化硅薄片^[11][,利用电化学等方法合成了具有特殊光阻性质的大孔氧化硅,氧化钛,金属以及合金材料等^[12],利用电化学等方法合成了具有特殊光阻性质的大孔氧化硅,氧化钛,金属以及合成材料等^[12],也有人利用相分离的方法制备无序大孔材料,但该方法一般较复杂,成本也比较昂贵,自然界中的大孔材料如海藻,珊瑚（氧化硅）是通过生物蛋白质为模板在基胞核内形成的,但是生物蛋白的模板作用和形成机理目前还不十分清楚。     

竖直浮动催化CVD法合成毫米级定向纳米碳纤维束

碳纳米管[1]和纳米碳纤维[2]的合成和应用是当前一维碳纳米材料理论和实验研究的焦点[3]。定向排列的碳纳米材料由于具有特殊的组织和性能[4~6],具有广泛的应用前景,例如,它可以作为优异的电子发射源,用于制作平板显示器等[6]。所有合成一维碳纳米材料的方法中[1,4,7],只有化学     

水溶性高分子量聚苯乙烯磺酸钠的制备

水溶性聚苯乙烯磺酸钠(PSS)是一种具有良好表面活性作用的高分子,近年来主要应用在碳纳米管的表面改性[1-2],工业废水处理中的助凝剂[3-4],聚合物接枝改性[5],晶体形貌生长调节剂[6-7],混凝土减水剂[8]等领域.     

树脂担载金催化苯胺衍生物氧化羰化制氨基甲酸甲酯

树脂类高聚物担载的各种过渡金属和贵金属催化剂在加氢、选择氧化、聚合、氢甲酰化等反应中已有应用^[1,2],金催化剂作为一种新型的催化材料正日益引起人们的重视。继无机氧化物担载金催化剂得到广泛使用后^[3-7],有机金催化下的醇醛缩合^[8]、烯烃羧化^[9]以及锡烷偶联^[10]等反应的效果亦很好。最近,我们将有机金配合物催化剂用于胺类化合物氧化羰化制取氨基甲酯的反应^ [11],结果很好。但该均相催化体系仍存在催化剂分离回收和重复使用困难等问题。我们将金担载于各种高聚物上并用于苯胺及其衍生物的氧化羰化时,发现使用大孔弱酸性阳离子交换树脂作为催化剂载体对该反应的活性很高。相对于以往广泛研究的钯、钌、铑等的各种配合物加助催化组分催化剂体系^[12-14],这一体系简单、高效、易分离,且能够重复使用。     

碳纳米管/氧化锌纳米复合材料的制备及其形貌控制

0引言碳纳米管(CNT)优良的力学、电学、热学性能使其在材料、储能、传感等许多领域都有广泛的应用前景,近年来,以碳纳米管为载体制备的纳米复合材料因其独特的应用潜力而受到广泛关注:彭峰等[1]用FeSO4-H2O2体系修饰碳纳米管,成功地制备了由碳纳米管负载的Fe2O3催化剂;Chen等[2]用溶胶凝胶法制备了CNT/SnO复合材料,作为Li离子电池阴极材料,测试表明它的电化学性能比单独的CNT和SnO材料都有所增强;Jitianu等[3]用溶胶凝胶和水热方法得到不同形貌的TiO2/CNT复合结构,这种新型的纳米复合材料在光催化方面有着重要的应用前景。纳米Z…     

碳纳米管负载高分散Pt纳米颗粒的制备及表征

近年来,碳纳米管(CNTs)[1]作为新型催化剂载体方面的研究[2～11]受到了广泛关注。由于碳纳米管具有纳米级卷曲的表面,与石墨烯相比其表面π键发生变化,从而导致新的电子结构[12],因此碳纳米管负载的催化剂在涉及电子传输过程的催化过程中具有特别的吸引力。燃料电池电极催化剂就是其中典型的一类[13～15]。已有研究者选用碳纳米管作为载体,将Pt[16～19]、PtRu[20,21]等具有催化活性的贵金属或其合金负载到碳纳米管上,展现出了很好的电催化氧化活性。然而,到目前为止,制备用于燃料电池的具有均匀尺寸和分散性的负载型纳米催化剂仍然是一项…     

CoO填充多壁碳纳米管作为锂离子电池负极材料

碳纳米管自1990年被日本科学家Iijima发现以来[1],由于其独特的结构组成而具有良好的强度和弹性模量、高比表面积、良好的耐腐蚀性和导电性等特点受到了广泛的关注,并已在催化剂载体、纳米电子器件、储能材料、复合功能材料等诸多领域得到应用。多壁碳纳米管(MWCNT)是由多层石墨卷绕而成的同心圆筒,石墨层间距约为0.034nm,管径一般为几十纳米,管长可达数微米,因此多壁碳纳米管具有较高的长径比,可以被看作一维纳米线。由于多壁碳纳米管在管壁之间和管腔之中存在大量空间,为锂离子的嵌入提供了可能,因此近年来关于多壁碳纳米管储锂的研究…     

低熔点晶体叠氮二乙基铝的合成和证明

叠氮二乙基铝（DEAA)是叠氮有机铝化合物中比较重要的一个化合物,但对DEAA的合成报道很少,还没有分离出纯的DEAA的报道。对它的研究有着重要的理论意义和应用价值。DEAA用作叠氮化试剂可用于多种叠氮化反应^[1-3];作为MOCVD前体物,由DEAA可制得性能优良的纳米级AIN材料,如AIN微晶薄膜^[4-6]和AIN粉末材料;DEAA是高含能材料,在国防和空间技术领域有着潜在的应用前景。文献报道的DEAA的合成方法按原料可分为三种^[7-10],其中以叠氮化钠和氯化二乙基铝（DEAC）为原料的合成方法应用较广,得到的DEAA为无色透明液体,熔点为－130℃^[11]。但笔者曾和到过固体DEAA^[12]。因此,本文将主要就DEAA的形态问题展开研究。     

炭化条件和铁系添加剂对炭分子筛性能影响的研究

炭分子筛(ＣａｒｂｏｎＭｏｌｅｃｕｌａｒＳｉｅｖｅ,以下简称ＣＭＳ)是具有特别发达的微孔结构的特种活性炭,在气体分离方面有广阔的应用前景[1]。目前作为变压吸附空气分离技术的首选吸附剂,在国内外被广泛用于中小规模的空气分离以制取富Ｎ2气体,制取ＣＭＳ的原料多是椰子壳、果核、植物、石油沥青及各种煤等[2,3]。煤是一种具有较为发达的孔隙结构的物质,且价格低廉,来源广泛,是制取ＣＭＳ的一种较为理想的原料。鸡西地区拥有丰富的煤炭资源,开发煤炭的深加工及高附加值产品具有十分重要的意义。本文以鸡西地区的烟煤为原料,制备空…     

Simulated moving bed technology with a simplified approach for protein purification. Separation of lactoperoxidase and lactoferrin from whey protein concentrate

Simulated moving bed (SMB) technology is a continuous chromatographic technique proven to have many advantages compared to conventional batch chromatography, such as: raised productivity and product concentration, reduced buffer consumption as well as more efficient use of raw material. In this study a 20 column SMB process for the separation of lactoperoxidase and lactoferrin from whey protein concentrate (WPC) was developed. A simplified approach with data from a single column experiment was used when designing the process. The SMB process data were compared to a theoretical scale-up of the breakthrough experiment reflecting the same 20 column set-up run in non-moving bed mode. The outcome of the comparison is a 48% raise in productivity, a 4.3 times decrease in buffer consumption, 6.5 times raise in target protein concentration with a raw material utilization which is slightly better for the SMB process.     

Selected-area growth of carbon nanotubes by the combination of focused ion beam and chemical vapor deposition techniques.

In this article, we report a technique for growing carbon nanotubes in a more controllable fashion, which enables us to synthesize nanotubes directly in various forms of designed patterns. This nanofabrication process is based on a combination of focused ion beam (FIB) and chemical vapor deposition (CVD) techniques. In this process, arrays of conductive patterns were first deposited on silicon substrates by directing a gaseous compound (C(9)H(16)Pt) via the capillary needle-sized nozzles within a FIB system. The substrates were then coated with catalyst and further modified by the FIB to localize the position of the catalyst. Finally, the growth of carbon nanotubes on the designed substrates was carried out by CVD of hydrocarbon gases. This fabrication technique has the advantage of positioning carbon nanotubes in selected locations. This may open up opportunities for the direct synthesis of carbon nanotubes onto almost any substrate material, thus allowing fabrication of carbon nanotube-based devices.     

Nanotube Content in Arc Generated Carbon Powder

 A novel experimental technique for the separation of nanotubes from other unwanted carbon species in arc generated carbon soot is described. A conjugated polymer was used to bind to nanotubes in solution. The resultant hybrid was soluble, whereas extraneous carbon material formed a sediment at the bottom of the sample bottle. The process was monitored using electron paramagnetic resonance (EPR) spectroscopy showing that 63% of nanotubes were kept in solution and 98.1% of impurities were rejected. This non-destructive purification allowed the calculation of the nanotube content in the carbon soot using EPR and thermogravimetric analysis (TGA). The measurement of nanotube content gave a purity value of 34% for the soot used in this study; this is compatible with estimates from electron microscopic determinations.     

Separation of carbon nanotubes by frit inlet asymmetrical flow field-flow fractionation

Flow field-flow fractionation (flow FFF), a separation technique for particles and macromolecules, has been used to separate carbon nanotubes (CNT). The carbon nanotube ropes that were purified from a raw carbon nanotube mixture by acidic reflux followed by cross-flow filtration using a hollow fiber module were cut into shorter lengths by sonication under a concentrated acid mixture. The cut carbon nanotubes were separated by using a modified flow FFF channel system, frit inlet asymmetrical flow FFF (FI AFIFFF) channel, which was useful in the continuous flow operation during injection and separation. Carbon nanotubes, before and after the cutting process, were clearly distinguished by their retention profiles. The narrow volume fractions of CNT collected during flow FFF runs were confirmed by field emission scanning electron microscopy and Raman spectroscopy. Experimentally, it was found that retention of carbon nanotubes in flow FFF was dependent on the use of surfactant for CNT dispersion and for the carrier solution in flow FFF. In this work, the use of flow FFF for the size differentiation of carbon nanotubes in the process of preparation or purification was demonstrated.     

Nanotube Content in Arc Generated Carbon Powder

Summary.  A novel experimental technique for the separation of nanotubes from other unwanted carbon species in arc generated carbon soot is described. A conjugated polymer was used to bind to nanotubes in solution. The resultant hybrid was soluble, whereas extraneous carbon material formed a sediment at the bottom of the sample bottle. The process was monitored using electron paramagnetic resonance (EPR) spectroscopy showing that 63% of nanotubes were kept in solution and 98.1% of impurities were rejected. This non-destructive purification allowed the calculation of the nanotube content in the carbon soot using EPR and thermogravimetric analysis (TGA). The measurement of nanotube content gave a purity value of 34% for the soot used in this study; this is compatible with estimates from electron microscopic determinations. Received June 23, 2000. Accepted July 3, 2000     

Structure of carbon onions and nanotubes formed by arc in liquids

Since carbon nanotubes and onions were discovered, many methods have been proposed for their production. For applications the main requirements are low capital cost, high purity of the produced material, simplicity of technique, and its potential for scale up. Recently a cathodic arc between two graphitic electrodes immersed in liquids has been demonstrated to be a simple method to produce carbon nanoparticles such as nanotubes and onions. In this paper high-resolution transmission electron microscopy is employed to examine the shape of the nanoparticles and the purity of the final material produced under various conditions. In this study we have used an arc discharge in two different liquids--liquid nitrogen and distilled water--and we have changed the grade of the carbon electrodes. The variety in structure, shape, and size of the produced particles is discussed in line with a model proposed to describe the physical process.     

利用沸腾床反应器制备碳纳米管

碳纳米管自1991年被日本NEC的Iijima发现以来,已经引起物理、化学和材料科学领域学者的广泛关注,并成为研究热点,理论和实验研究表明,碳纳米管具有独特的电学和力学性质,其导电性与管本身的直径和管的螺旋度有关,随着这些参数的变化,碳纳米管可表现出导体或半导体的性质。扬氏模量的测量表明,碳纳米管具有极高的强度,这些都预示着它具有广泛的应用前景。     

原煤可磨性对气流床粉煤气化混配煤煤粉均匀程度的影响

以气流床粉煤气化工业装置不同时期的两组进料煤粉为研究对象,在实验室按粒径对两组煤粉进行了筛分分组,对分组后子煤粉进行了煤质、煤灰特性及反应活性分析,研究了原煤可磨性差异对混配磨制后煤粉均匀程度的影响。结果表明,原煤可磨性对混煤煤粉的颗粒粒径分布及其均匀性均具有影响。混配磨制煤粉的粒径主要取决于原煤中可磨性指数较小的原煤,此原煤可磨性指数越小,煤粉颗粒粒径越大;可磨性相近的原煤混配制得的煤粉混合较均匀,可磨性差异较大的原煤混配煤粉混合不均,煤粉发生偏析,使得大颗粒煤粉中含有过多的难磨煤,导致煤粉的反应性能变差。