硝基苯加氢合成对氨基酚用负载铂催化剂的制备

 用甲醛还原沉积法制备了活性炭负载的铂催化剂（Pt／AC）和不\r\n同载体负载的铂催化剂，并考察了催化剂对硝基苯加氢制备对氨基酚反\r\n应的催化性能．结果表明，还原Pt（Ⅳ）的甲醛用量是影响催化剂性能\r\n的关键因素，甲醛必须过量而且存在一个最佳值．增加催化剂的铂负载\r\n量，不能有效提高加氢反应速度，反而易降低对氨基酚选择性；低铂负\r\n载量催化剂具有较高的活性、选择性及稳定性．XPS和TEM表征结果表明\r\n，金属铂集中分布于活性炭颗粒外部，其颗粒大小介于2～12nm间．炭\r\n载体催化剂的活性和选择性明显高于金属氧化物载体催化剂．掺入适量\r\n的Mg可显著提高Pt／AC催化剂的活性和选择性．     

非均相催化一步合成碳酸二苯酯的研究 Ⅰ.载体制备方法对催化剂性能的影响

 采用溶胶－凝胶法、共沉淀法和冷冻干燥法，制备了LaxMnyPbz\r\nO复合型金属氧化物载体，并以PdCl2或Na2PdCl4的水溶液为浸渍液，通\r\n过浸渍方法制得固相催化剂，用于一步合成碳酸二苯酯．用XRD，TEM及\r\nSEM对载体及催化剂进行了表征．结果表明，三种载体的主要物相皆为\r\nLa0．3Mn0．5PbO，溶胶－凝胶法制得的载体及催化剂的粒径分布较好\r\n，空隙率较大，活性组分分散度较高；溶胶－凝胶法制得的催化剂的催\r\n化性能较好，碳酸二苯酯选择性可高于99．5％．     

钼催化剂上甲醇直接气相羰基化活性与吸附的关系

 制备了一系列非负载的钼催化剂，考察了催化剂上甲醇直接气相\r\n羰化活性与反应物及产物吸附的关系．结果发现，催化剂的制备方法对\r\n甲醇直接气相羰化活性的影响很明显，以纯二硫化钼试剂制备的催化剂\r\n，甲醇转化率与羰化产物乙酸甲酯的选择性最低；以三氧化钼气相还原\r\n硫化制备的催化剂，其羰化活性较低；以钼酸铵溶液经硫化铵溶液或硫\r\n化氢气体硫化制得的催化剂，其性能明显优于前两种，尤以钼酸铵经硫\r\n化铵溶液硫化制得的催化剂的性能最佳．催化剂的羰化活性明显依赖于\r\n催化剂的吸附性能，羰化活性高的催化剂不仅吸附CO的量大，而且对甲\r\n醇和乙酸甲酯的吸附量也明显较大．     

天然气-二氧化碳-水蒸气-氧转化制合成气的研究: 稀土助剂的作用

 研究了稀土氧化物（CeO2和La2O3）改性的镍基催化剂中助剂的\r\n作用，并考察了催化剂对天然气－二氧化碳－水蒸气－氧转化制合成气\r\n反应的活性．结果表明，La2O3改性的镍基催化剂具有较高的CH4转化率\r\n和H2选择性；经CeO2改性的镍基催化剂具有较高的CO选择性．量子化学\r\n计算和XRD研究结果表明，La2O3助剂的加入，可使还原后催化剂表面N\r\ni（111）晶面衍射峰的强度减小，较好地符合吸附活化CH4分子的“尺\r\n寸效应”和能量要求．添加CeO2助剂的催化剂，其Ni（111）晶面衍射\r\n峰强度较大，而Ni（110）晶面含量最小，不利于CH4的离解．同时，助\r\n剂RE2O3（尤其是CeO2）和MgO提高了Ni的d电子密度，因而一定程度上\r\n加强了Nid电子向CO2空反键π轨道的迁移，促进CO2分子的活化，提高\r\n其消碳活性．     

Re/HZSM-5体系上的甲烷无氧芳构化反应

 与Mo／HZSM－5相比，Re／HZSM－5也是较好的甲烷无氧芳构化催\r\n化剂，其初活性较高，但随着反应的进行，催化剂失活的速率较快．通\r\n过NH3－TPD，H2－TPR和MASNMR等手段，对催化剂的酸性和分子筛骨架\r\n铝的变化以及铼物种的还原性能进行了研究．结果表明，催化剂酸性的\r\n在反应中起着重要的作用，但不同铼担载量的催化剂酸性的变化比较复\r\n杂，不同于Mo／HZSM－5体系．总的来看，并不是酸性越强或酸量越多\r\n，催化剂的催化性能就越好；催化剂的酸性和酸量都有一个最佳值．担\r\n载铼物种后，铼物种可与分子筛的骨架铝发生强烈的相互作用，最终导\r\n致骨架脱铝．Re／HZSM－5催化剂具有较高的低温活性，在较低温度下\r\n可被还原性气氛还原，且还原后的活性物种单一．     

氧化铝负载钌基氨合成催化剂的制备条件及载体改性

 利用等体积浸渍法制备了氧化铝负载钌基氨合成催化剂．考察了\r\n氢氧化铝的焙烧温度，催化剂的还原温度，助剂K、Ba和Sm的添加，以\r\n及用MgO和BaO改性氧化铝载体等对催化剂活性的影响．通过XRD，N2物\r\n理吸附和CO2化学吸附等方法表征了载体的物相结构、比表面积和表面\r\n碱性．研究结果表明，氧化铝表面碱性随着氢氧化铝焙烧温度的升高而\r\n增大是催化剂活性升高的主要原因，载体比表面积的降低对催化剂活性\r\n的影响相对较小．助剂K、Ba和Sm的加入显著地提高了催化剂的活性，\r\n同时助剂Ba和Sm还减弱了强吸附氢对氮吸附的抑制作用，明显提高了催\r\n化剂的高压活性．用MgO改性氧化铝载体降低了其比表面积，但是显著\r\n地提高了载体的表面碱性和催化剂的活性．BaO改性的氧化铝载体的比\r\n表面积、表面碱性及其负载的钌基催化剂的活性随着BaO含量的增加先\r\n升高后降低，当BaO摩尔含量为7．7％时，催化剂活性最高．     

纳米二氧化锆催化剂上一氧化碳加氢合成异丁烯

 考察了纳米ZrO2的制备方法及Al2O3和KOH助剂的添加对ZrO2催化\r\nCO加氢合成异丁烯反应的影响．纳米ZrO2的制备方法对ZrO2的物理性质\r\n和催化性能有较大的影响．用超临界流体干燥法干燥并在流动N2气氛中\r\n焙烧制得的ZrO2催化剂对异丁烯具有较高的选择性．Al2O3和KOH助剂表\r\n现出非常优良的助剂效应，在大幅度提高催化剂对i－C4烃选择性的同\r\n时保持了和ZrO2同样高的催化活性．催化剂的酸碱性表征结果表明，酸\r\n碱性对催化剂的催化性能影响很大，催化剂上适宜的酸碱数量和酸碱比\r\n例是影响其催化CO加氢合成异丁烯性能的非常重要的因素．     

制备蜂窝状筛网进行NH3选择性催化还原NO的反应

 制备了蜂窝状筛网催化剂，并用于以NH3为还原剂选择性催化还\r\n原NO的反应．蜂窝状筛网催化剂具有热响应迅速、传质系数较高、压力\r\n降适中、机械强度较高、几何可变形性、抗热震性能好、催化剂回收简\r\n便和成本较低等一系列优点．阐述了蜂窝状筛网催化剂的制备工艺，并\r\n采用扫描电镜、比表面积测定、X射线衍射、活性评价等手段考察了筛\r\n网预处理方法对其催化活性的影响．实验结果表明，最佳的预处理方法\r\n是首先经稀酸刻蚀，然后于500℃下焙烧20h．     

Ni含量及预硫化对NiW/γ-Al2O3催化剂上噻吩加氢脱硫反应活性的影响

 采用连续流动微反装置考察了活性组分Ni／（Ni＋W）原子比及\r\n预硫化条件对NiW／γ－Al2O3催化剂噻吩加氢脱硫（HDS）反应活性的\r\n影响．用X射线光电子能谱和电镜微区元素分析方法对硫化态催化剂进\r\n行了表征．结果表明，催化剂的组成、硫化方法、硫化度和反应条件等\r\n都能影响NiW／γ－Al2O3催化剂的HDS反应活性．对于在较低温度（30\r\n0℃）下硫化的催化剂，当反应温度较低（260～290℃）时，最佳Ni／\r\n（Ni＋W）原子比为0．50，而当反应温度较高（330～360℃）时，最佳\r\nNi／（Ni＋W）原子比为0．23．当催化剂在300～450℃下硫化时，其噻\r\n吩HDS反应活性随硫化温度升高而增大，表明硫化度较高的催化剂具有\r\n较高的HDS反应活性．     

制备方法对Pd催化剂上丙烯选择性还原NO反应性能的影响

 采用三种不同方法制备了氧化铝负载的Pd催化剂．比表面积测定\r\n结果表明,与浸渍法相比,溶胶－凝胶加浸渍法和溶胶－凝胶法制备的\r\nPd／Al2O3样品具有较大的比表面积,但抗烧结性能不佳．其中采用溶\r\n胶－凝胶法制备的样品中,由于Pd分散于体相中,表面的活性位相对较\r\n少,造成催化剂在NO选择性还原反应中的活性较差;而将Pd浸渍于溶胶\r\n－凝胶法制得的Al2O3载体上所获得的催化剂比表面积较大,活性较好\r\n．添加CeO2的样品活性总体上比Pd／Al2O3样品高．其中采用溶胶－凝\r\n胶法制备的样品比表面积不大,并且XRD数据表明Al2O3和CeO2是高度分\r\n散并均匀地搀杂在一起的,不象在浸渍法制备的样品中那样以大晶粒的\r\n形式存在,因而CeO2的助剂作用没有充分体现出来,催化剂的活性比浸\r\n渍法制备的样品差一些．     

Comparing the deactivation behaviour of Co/CNT and Co/γ-Al2O3 nano catalysts in Fischer-Tropsch synthesis

An extensive study of Fischer-Tropsch (FT) synthesis on cobalt nano particles supported on γ-alumina and carbon nanotubes (CNTs) catalysts is reported.20 wt% of cobalt is loaded on the supports by impregnation method.The deactivation of the two catalysts was studied at 220 C,2 MPa and 2.7 L/h feed flow rate using a fixed bed micro-reactor.The calcined fresh and used catalysts were characterized extensively and different sources of catalyst deactivation were identified.Formation of cobalt-support mixed oxides in the form of xCoO yAl2O3 and cobalt aluminates formation were the main sources of the Co/γ-Al2O3 catalyst deactivation.However sintering and cluster growth of cobalt nano particles are the main sources of the Co/CNTs catalyst deactivation.In the case of the Co/γ-Al2O3 catalyst,after 720 h on stream of continuous FT synthesis the average cobalt nano particles diameter increased from 15.9 to 18.4 nm,whereas,under the same reaction conditions the average cobalt nano particles diameter of the Co/CNTs increased from 11.2 to 17.8 nm.Although,the initial FT activity of the Co/CNTs was 26% higher than that of the Co/γ-Al2O3,the FT activity over the Co/CNTs after 720 h on stream decreased by 49% and that over the Co/γ-Al2O3 by 32%.For the Co/γ-Al2O3 catalyst 6.7% of total activity loss and for the Co/CNTs catalyst 11.6% of total activity loss cannot be recovered after regeneration of the catalyst at the same conditions of the first regeneration step.It is concluded that using CNTs as cobalt catalyst support is beneficial in carbon utilization as compared to γ-Al2O3 support,but the Co/CNTs catalyst is more susceptible for deactivation.     

催化反应制备碳化硅纳米粉体的密度泛函理论计算及实验研究

以Si_(55),Si_(43)M_(12)和Si_(37)M_(18)(M=Fe,Co或Ni)团簇为模型,采用密度泛函理论(DFT)研究了Fe,Co及Ni纳米团簇催化硅粉转化为SiC的机理.计算结果表明,Fe,Co及Ni纳米催化剂先与Si形成合金,拉长并弱化Si—Si键的强度,起到活化Si粉的作用;合金的形成有利于C原子的吸附及Si原子和C原子间的反应;Fe的催化能力强于Co和Ni.在此基础上,以Si粉和酚醛树脂为原料,以Fe,Co及Ni硝酸盐为催化剂前驱体,通过微波加热反应制备了3C-SiC纳米粉体.研究了催化剂种类、反应温度、催化剂用量和反应时间等对制备3C-SiC纳米粉体的影响.结果表明,催化剂Fe,Co和Ni的加入均可显著降低3C-SiC的合成温度.当以2.0%(质量分数)的Fe为催化剂时,Si粉在1100℃下反应30 min后即可全部转化为3C-SiC纳米粉体;而在相同条件下,无催化剂时Si粉的完全转化温度为1250℃;Fe的催化效果优于Co和Ni,与DFT计算结果吻合.     

水促进Co/Mo/Al2O3催化剂上碳纳米管的生长

对水促进Co/Mo/Al2O3催化剂裂解乙烯生长碳纳米管(CNTs)的研究发现,通入体积分数(φ)为0.6％的水蒸汽在1h内可将CNTs的生长倍率从3.7 g·g-1提高至70 g·g-1.水的作用在于恢复被无定形碳包覆的催化剂颗粒的活性,水的加入量由于其积碳(促进同体碳生成)和消碳(去除固体碳)的竞争作用而存在最佳值.不同反应时间下乙烯的转化率与有效催化剂含量的分析表明,在CNTs生长后期,水的催化促进作用减弱.将催化剂的相对活性与CNT聚团的相对密度关联发现,反应后期的CNTs主要在聚团内部缠绕生长,催化剂被包覆失活.拉曼测试与差热热重分析表明,生长阻力导致所得CNTs缺陷增多,CNT聚团密度变化与CNT缺陷间存在对应关系.聚团内外CNTs的生长阻力不同,生长倍率不同,导致产品纯度不均匀.     

石墨烯负载镍催化CO_2加氢甲烷化

采用改进的Hummers法制备了氧化石墨烯(GO),经水合肼还原得到石墨烯(RGO),通过浸渍法制备了石墨烯负载的镍基催化剂(Ni/RGO);对其催化二氧化碳甲烷化反应的性能进行了研究,并与以碳纳米管(CNTs)和活性炭(AC)为载体负载的Ni基催化剂进行了比较.由于催化剂的载体分别为RGO,CNTs和AC,所以Ni将会表现出不同的形态.利用红外光谱(FTIR)、比表面积(BET)测试、程序升温还原(H2-TPR)、X射线衍射(XRD)分析和透射电子显微镜(TEM)等表征手段对其结构及物理性质进行了表征.结果表明,Ni/RGO具有相对较大的比表面积(316 m~2/g),Ni在Ni/RGO上的颗粒尺寸(5.3 nm)小于其在Ni/CNTs(8.9 nm)和Ni/AC(11.6 nm)上的颗粒尺寸;该催化剂在二氧化碳甲烷化反应中具有更高的催化活性和选择性,而且具有良好的使用寿命.     

助剂铬对Ni/MgO催化剂CVD法制备碳纳米管的促进作用

采用溶胶-凝胶法制备了助剂Cr改性的Ni/MgO催化剂, 用化学气相沉积(CVD)法在600 ℃下裂解甲烷生长碳纳米管, 研究了助剂Cr的引入对催化剂微结构和制备碳纳米管性能的影响. 催化剂样品用XRD, TPR和CO-TPD进行了分析, 制备的碳纳米管用TEM和XRD进行了表征. 实验结果表明, NiO和MgO之间存在着强相互作用而形成固溶体, Ni/MgO催化剂经氢气处理后其中的镍氧化物只有极少部分被还原成为镍. 助剂铬的引入明显促进了镍的还原, 使得催化剂表面的Ni活性中心数增多, 从而使催化剂的活性和性能得到了明显的改进. 在加入助剂后碳纳米管的产率明显增加, 当Cr质量分数为8%时, 碳纳米管的产量为未加助剂时产量的5倍, 碳纳米管和催化剂的质量比达到1928. 当Cr含量进一步增加时, Ni在催剂表面聚集形成大颗粒, 制备出的产品中含有大量的碳纳米纤维和无定形碳. 以8%Cr-Ni/MgO催化剂合成的碳纳米管具有比较高的产率且质量较好.     

Synthesis and characterization of Pd catalysts supported on carbon microspheres for formic acid oxidation

A facile preparation of Pd catalyst using carbon microspheres as support was introduced in this paper. The carbon microspheres were prepared with a simple method from dextrose via hydrothermal process and used as catalysts support for formic acid electrooxidation. Transmission electron microscopy (TEM) and X-ray diffraction (XRD) analyses revealed that the as-prepared face-centered cubic crystal Pd nanoparticles were well-dispersed on the surface of the carbon microspheres, and the mean diameter of the nanoparticles was 8.8 nm. The effect of the support on the catalyst performance for formic acid electrooxidation was studied. The as-prepared catalyst showed the enhanced electrochemical surface active area and the higher electrocatalytic activity towards formic acid oxidation compared with Pd/CNTs and Pd/XC-72 catalysts prepared at room temperature. Electrochemical analysis suggested that the carbon microspheres might be good candidates to be used as the supports of catalyst for formic acid electrochemical oxidation.     

Fe/炭黑、Ni/炭黑催化剂对渣油加氢反应的影响

使用模型化合物在微型反应釜中研究了载体炭黑对渣油内部氢转移反应的影响。结果表明，炭黑可以明显地促进四氢萘到蒽的氢转移反应。使用等体积浸渍法制备了Fe/炭黑、Ni/炭黑催化剂并对Fe/炭黑催化剂进行了XRD、SEM表征，结果表明，金属硫化物附着在炭黑颗粒的表面，直径为1μm左右。在高压反应釜中研究了载体炭黑和以炭黑为载体的催化剂对克拉玛依常压渣油430℃加氢反应的影响，并于传统的水溶性分散型催化剂的抑焦性能进行了对比。 结果表明，Fe/炭黑、Ni/炭黑催化剂可以明显地抑制渣油加氢反应的生焦，水洗后的催化剂效果比未经水洗的催化剂抑制生焦的效果好；Ni/炭黑催化剂抑焦效果比Fe/炭黑催化剂好；Fe/炭黑催化剂比同等浓度的水溶性Fe催化剂抑焦效果好。对反应产物馏分的分析表明，Fe/炭黑催化剂可以有效地抑制渣油缩合生焦，同时在一定程度上抑制裂化反应。     

Growth, new growth, and amplification of carbon nanotubes as a function of catalyst composition

Carbon nanotubes (CNTs) have been grown using Fe, Co, Ni, and Co/Fe spin-on-catalyst (SOC) systems, involving the metal salt dispersed with a spin-on-glass precursor. During initial growth runs (CH4/H2/900 degrees C), the CNT yield followed the order Co-SOC > Fe-SOC > Ni-SOC. The Fe catalysts produced the longest nanotubes at the expense of a larger average CNT diameter and broader diameter distribution than the Co-SOC system. A series of Co/Fe-SOCs were prepared where as the atomic percentage of Co is increased nucleation of CNT increases but the CNT length decreases. The linear relationship between the diameter and length of CNTs grown from the Co/Fe-SOC suggests that slow growth is beneficial with respect to control over CNT diameter. After initial CNT growth, the original samples were subjected to additional growth runs. Four individual reactions were observed in the Fe-SOC and binary Co/Fe-SOC: regrowth (amplification), double growth (a second CNT growing from a previously active catalyst), CNT etching, and nucleation from initially inactive catalysts (new growth). CNT etching was observed for the mixed catalyst systems (Co/Fe-SOC) but not for either Fe-SOC or Co-SOC. During the regrowth experiments, CNTs were observed that were not present after the initial growth run (and were not as a result of amplification or double growth). Thus, catalysts, which were initially inactive toward nucleation of CNTs in the original growth run, are capable of becoming activated when placed back into the furnace and submitted to regrowth under identical conditions.     

Enhancement of bimetallic Fe-Mn/CNTs nano catalyst activity and product selectivity using microemulsion technique

Bimetallic Fe-Mn nano catalysts supported on carbon nanotubes(CNTs) were prepared using microemulsion technique with water-to-surfactant ratios of 0.4-1.6. The nano catalysts were extensively characterized by different methods and their activity and selectivity in Fischer-Tropsch synthesis(FTS) have been assessed in a fixed-bed microreactor. The physicochemical properties and performance of the nanocatalysts were compared with the catalyst prepared by impregnation method. Very narrow particle size distribution has been produced by the microemulsion technique at relatively high loading of active metal. TEM images showed that small metal nano particles in the range of 3–7 nm were not only confined inside the CNTs but also located on the outer surface of the CNTs. Using microemulsion technique with water to surfactant ratio of0.4 decreased the average iron particle sizes to 5.1 nm. The reduction percentage and dispersion percentage were almost doubled. Activity and selectivity were found to be dependent on the catalyst preparation method and average iron particle size. CO conversion and FTS rate increased from 49.1% to 71.0% and 0.144 to 0.289 gHC/(gcat h), respectively. While the WGS rate decreased from 0.097 to 0.056 gCO2/(gcat h). C5+liquid hydrocarbons selectivity decreased slightly and olefins selectivity almost doubled.     

Study of correlations between the physicochemical properties of carbon nanotubes and the type of catalyst used for their synthesis

It is found that carbon nanotubes (CNTs) obtained by the catalytic pyrolysis of ethanol vapor with Ni-, Co-, and Fe catalysts vary in their ability to oxidative modification and, finally, in adsorption capacity, dispersion, and the texture of the synthesized powders. The adsorption capacity of the modified CNTs varies in the order Ni > Co > Fe. The material obtained with a Ni catalyst has good bulk and hydrodynamic properties, which is essential for use in chromatographic columns. Using a Fe catalyst, a loose, cotton wool-like product was obtained that is unsuitable for column chromatography, and with a Co catalyst, a material with intermediate properties was synthesized. Differences in the physicochemical properties of CNTs are related to the morphology of the products.