焙烧温度对Ni/MgO催化剂结构及其在甲苯二氧化碳重整反应中催化性能的影响(英文)

考察了焙烧温度对 Ni/MgO 催化剂结构及其在甲苯二氧化碳重整反应中催化性能的影响. 由于 NiO-MgO 固溶体的形成,样品的 X 射线衍射谱中没有出现明显的 NiO 衍射峰, 而在拉曼光谱中出现明显的散射信号. X 射线光电子能谱、氢气程序升温还原和 H2脉冲吸附结果表明, 高温焙烧过程中 Ni 向催化剂体相扩散, 与 MgO 发生强互相互作用, 使得 Ni 物种难以还原,但部分位于催化剂表面的 Ni 物种能够还原; 高温焙烧后催化剂表面活性 Ni 物种明显减少, 致使催化剂重整活性降低. 重整反应后, 催化剂表面存在少量多核芳烃类积炭, 这很可能是高温焙烧催化剂稳定性差的原因.     

焙烧及还原温度对对硝基苯酚加氢合成对氨基苯酚Ni/TiO2催化剂性能的影响

采用等体积浸渍法制备了Ni/TiO2催化剂,考察了焙烧和还原温度对其结构及催化对硝基苯酚加氢合成对氨基苯酚反应性能的影响,利用X射线衍射、程序升温还原及H2化学吸附等方法对催化剂进行了表征.结果表明,923 K以下焙烧制备的催化剂中镍物种主要以与载体相互作用不同的NiO形式存在,随着焙烧温度的升高,催化剂中NiO与TiO2间的相互作用增强.经723 K还原后,随焙烧温度升高,催化剂的H2化学吸附量减小,而923 K焙烧的催化剂具有较佳的加氢反应性能,这与金属镍和TiOx(x<2)的协同作用有关.对于923 K焙烧的催化剂,当还原温度较低时,NiO还原不完全,金属镍与TiOx的相互作用较弱,催化剂活性较低;当还原温度过高时,镍晶粒发生烧结,并且催化剂的镍活性表面因镍与TiOx的相互作用增强而减小,从而导致催化剂活性降低,适宜的还原温度为673 K.当Ni/TiO2催化剂具有适宜的镍活性表面及适宜的金属镍与TiOx相互作用时,金属镍与TiOx的协同对-NO2的加氢活化最为有利.     

Ni/HZSM-5催化剂的结构及其催化山梨醇水相加氢合成烷烃性能

采用浸渍法制备了Ni/HZSM-5双功能催化剂,考察了焙烧温度对催化剂结构及其催化山梨醇水相加氢合成C5～C6烷烃性能的影响.结果表明,在金属中心和酸性载体的协同作用下,通过山梨醇中C-O键加氢和异构化高选择性合成了C5～C6烷烃.经500°C焙烧的Ni/HZSM-5催化剂上山梨醇水相加氢的活性最高,山梨醇转化率为62.0%,戊烷和己烷的总选择性为76.4%,其中异己烷选择性达45.4%.对催化剂进行N2物理吸附、X射线衍射、NH3程序升温脱附和H2程序升温还原等表征后发现,经500°C焙烧催化剂的有效比表面积和孔体积均明显增大,HZSM-5负载的硝酸镍分解成较小晶粒的NiO,表面酸量适中,且Ni物种与载体相互作用较强,较易被H2还原,Ni还原度达100%.这是其催化活性最高的原因.     

无氯 Cu/AC 催化剂的制备及其催化气相甲醇氧化羰基化反应性能

 以 Cu2(NO3)(OH)3/AC (活性碳) 为催化剂前驱体, 在惰性气氛中于不同温度热处理分别制得无氯的 CuO/AC, Cu2O/AC 和 Cu0/AC 催化剂, 并用于甲醇直接气相氧化羰基化合成碳酸二甲酯 (DMC) 反应. 结果表明, 200 °C 处理制得的催化剂中, Cu 物种以 CuO 为主. 随着处理温度的升高, 催化剂中 CuO 含量逐渐降低, 而 Cu2O 含量增加; 400 °C 制备的催化剂中, Cu 物种仅以 Cu2O 形式存在; 而 450 °C 以上处理时则以 Cu0 形式存在. 随着热处理温度的提高, 相应催化剂活性逐渐增加, 表明 CuO, Cu2O 和 Cu0 均具有催化活性, 其活性大小的顺序为 CuO < Cu2O < Cu0. 在 140 °C, CO:MeOH:O2 = 4:10:1, SV = 5 600 h1 条件下, 450 °C 处理制备的 Cu0/AC 催化剂表现出较高的催化甲醇氧化羰基化活性, 其中甲醇转化率达 11.5%, DMC 的时空收率和选择性分别为 261.9 mg/(g•h) 和 76.0%.     

NiO-MgO固溶体的形成对Ni/MgO-AN催化CO2重整CH4反应活性和稳定性的影响

 以在流动N2中热处理的Mg(OH)2醇凝胶制得的纳米氧化镁(MgO-AN)为载体,浸渍Ni(NO3)2后经不同温度焙烧得到Ni含量为8.8%的NiO/MgO样品,还原后制得Ni/MgO-AN催化剂. 采用XRD和TPR技术对NiO和MgO之间形成的NiO-MgO固溶体进行了表征,并将Ni/MgO-AN催化剂用于催化CO2重整CH4反应. 结果表明,在低于650 ℃焙烧时, NiO不能完全溶入MgO中,NiO/MgO样品中存在自由的NiO粒子,还原态Ni/MgO-AN催化剂在CO2重整CH4反应中的稳定性低; 当样品焙烧温度等于或高于650 ℃时,NiO可以完全溶入MgO中形成NiO-MgO固溶体,还原态Ni/MgO-AN催化剂具有高稳定性.     

TiO2-Al2O3载体的制备及Ni2P/TiO2-Al2O3催化剂上的同时加氢脱硫和加氢脱氮反应

 以溶胶-凝胶法制备的 TiO2-Al2O3 复合氧化物为载体, 采用浸渍法制备了 Ni2P/TiO2-Al2O3 催化剂, 并用 X 射线衍射、N2 吸附脱附、红外和 X 射线光电子能谱等技术对催化剂进行了表征, 考察了载体中 TiO2 含量、焙烧温度及其制备方法对 Ni2P/TiO2-Al2O3 催化剂上同时进行噻吩加氢脱硫和吡啶加氢脱氮反应的影响. 结果表明, 以 Ni/P 摩尔比为 1/2 的前驱体制备的催化剂表面仅出现 Ni2P 物相; 当载体中 TiO2 的含量为 80%, 焙烧温度为 550 oC 时, Ni2P/TiO2-Al2O3 催化剂上加氢脱硫和加氢脱氮的活性最高. 在 360 oC, 3.0 MPa, 氢/油体积比 500, 液时体积空速 2.0 h?1 的条件下, 噻吩和吡啶转化率分别为 61.3%和 64.4%.     

Ni/SiO_2催化甲烷裂解制氢和纤维炭

甲烷催化裂解制氢具有过程简单、产物易分离、无CO_x产生等优点,是一种潜在的制氢工艺。本工作采用浸渍法制备Ni/SiO_2介孔催化剂,通过N2吸附-脱附、X射线衍射、程序升温还原、扫描电子显微镜和透射电子显微镜对反应前后的催化剂结构及生成炭的形貌进行表征,研究了焙烧温度、金属负载量和反应温度对其甲烷催化裂解性能的影响。结果表明,所制备的Ni/SiO_2催化剂具有较好的介孔结构,焙烧温度对催化剂的结构性质和催化性能影响较小,但会改变Ni晶粒在催化剂表面团聚程度。随着金属负载量的增加,催化剂的活性呈现先增加后降低的趋势,其中30%Ni/SiO_2催化剂的催化活性最佳。反应温度会显著影响催化剂的活性、稳定性以及生成炭的形态;较高反应温度导致催化剂的稳定性降低和包覆炭的形成。在30%Ni/SiO_2催化剂上、550°C下反应1000 min,甲烷转化率为9.8%,纤维炭产率约为650°C下的7.2倍。     

制备条件对Ni/ZrO2-SiO2催化剂煤气甲烷化的影响

采用浸渍法制备了ZrO₂-SiO₂复合载体和Ni质量分数为6%的Ni/ZrO₂-SiO₂催化剂,考察了载体制备时浸渍溶液pH值、焙烧温度和催化剂制备时的焙烧温度对Ni/ZrO₂-SiO₂催化剂煤气甲烷化反应性能的影响。采用X射线衍射、程序升温还原和扫描电子显微镜等方法对催化剂进行了表征。结果表明,载体浸渍溶液pH值为8.0～9.0, 载体焙烧温度为550 ℃,催化剂焙烧温度为450 ℃时,Ni/ZrO₂-SiO₂催化剂在煤气甲烷化反应中显示了最优的催化性能,CO转化率100%,CO₂转化率1.8%,CH₄生成速率16.6 mmol/(h·g)。进一步表征发现,制备ZrO₂-SiO₂复合载体时,增大浸渍溶液的pH值有利于形成粒径较小的亚稳态四方晶相ZrO₂,可见四方晶相ZrO₂更有利于甲烷化反应;载体焙烧温度会影响到NiO粒径的大小和其在催化剂表面的分散,温度过高和过低都会导致NiO粒径大小的不适宜以及分散性的降低;催化剂焙烧温度过高则会导致NiO与载体间的相互作用减弱,NiO分散性降低。     

超高温焙烧的Ni/Al2O3对甲烷部分氧化反应的催化活性

考察了超高温焙烧的Ni/Al2O3对甲烷部分氧化反应的催化性能,发现该催化剂经还原后对甲烷部分氧化反应表现出较高的催化活性.X射线衍射结果显示,Ni/Al2O3催化剂在超高温(1200~1400℃)下焙烧后生成了NiAl2O4,且无相转移,进一步经950℃还原后催化剂中绝大部分Ni以单质Ni0形式存在.透射电子显微镜测试结果表明,不同超高温焙烧的催化剂经950℃还原后Ni晶粒的大小无明显差异.这说明超高温焙烧的Ni/Al2O3对甲烷部分氧化反应的高活性可归结为NiAl2O4的可还原性以及还原后Ni0相似的晶粒尺寸.同时还发现,焙烧温度越高,生成的NiAl2O4的还原温度越高.     

Effect of preparation condition on catalytic performance of Ni/ZrO2-SiO2 for methanation of coal gas

采用浸渍法制备了ZrO2-SiO2复合载体和Ni质量分数为6％的Ni/ZrO2 -SiO2催化剂,考察了载体制备时浸渍溶液pH值、焙烧温度和催化剂制备时的焙烧温度对Ni/ZrO2-SiO2催化剂煤气甲烷化反应性能的影响.采用X射线衍射、程序升温还原和扫描电子显微镜等方法对催化剂进行了表征.结果表明,载体浸渍溶液pH值为8.0 ～9.0,载体焙烧温度为550℃,催化剂焙烧温度为450℃时,Ni/ZrO2-SiO2催化剂在煤气甲烷化反应中显示了最优的催化性能,CO转化率100％,CO2转化率1.8％,CH4生成速率16.6 mmol/(h·g).进一步表征发现,制备ZrO2-SiO2复合载体时,增大浸渍溶液的pH值有利于形成粒径较小的亚稳态四方晶相ZrO2,可见四方晶相ZrO2更有利于甲烷化反应;载体焙烧温度会影响到NiO粒径的大小和其在催化剂表面的分散,温度过高和过低都会导致NiO粒径大小的不适宜以及分散性的降低;催化剂焙烧温度过高则会导致NiO与载体间的相互作用减弱,NiO分散性降低.     

A novel Ni(4) complex exhibiting microsecond quantum tunneling of the magnetization

A highly asymmetric Ni(II) cluster [Ni(4)(OH)(OMe)(3)(Hphpz)(4)(MeOH)(3)](MeOH) (1) (H(2)phpz=3-methyl-5-(2-hydroxyphenyl)pyrazole) has been prepared and its structure determined by means of single-crystal X-ray diffraction by using synchrotron radiation. Variable-temperature bulk-magnetization measurements show that the complex exhibits intramolecular-ferromagnetic interactions leading to a spin ground state S=4 with close-lying excited states. Magnetization and high-frequency EPR measurements suggest the presence of sizable Ising-type magnetic anisotropy, with zero-field splitting parameters D=-0.263 cm(-1) and E=0.04 cm(-1) for the spin ground state, and an isotropic g value of 2.25. The presence of both axial and transverse anisotropy was confirmed through low-temperature specific heat determinations down to 300 mK, but no slow relaxation of the magnetization was observed by AC measurements down to 1.8 K. Interestingly, AC susceptibility measurements down to temperatures as low as 23 mK showed no indication of slow relaxation of the magnetization in 1. Thus, despite the presence of an anisotropy barrier (U approximately 4.21 cm(-1) for the purely axial limit), the magnetization relaxation remains extremely fast down to the lowest temperatures. The estimated quantum tunneling rate, Gamma>0.667 MHz, makes this complex a prime candidate for observation of coherent tunneling of the magnetization.     

载体对负载型Ni-B催化剂催化2-乙基蒽醌加氢制H2O2反应性能的影响

采用还原剂浸渍法将Ni-B非晶态合金负载到SiO2,γ-Al2O3和活性炭(AC)上,以2-乙基蒽醌选择加氧制H2O2为探针反应,系统研究了载体对Ni-B非晶态合金催化剂结构、热稳定性和催化性能的影响.结果表明,将Ni-B负载到载体上后,其晶化温度显著提高,各催化剂热稳定性依次为Ni-B/AC＞Ni-B/SiO2＞Ni...     

镍前驱体对非负载型镍催化剂上甲烷分解活性的影响

 分别以硝酸镍和乙酸镍为前驱体, 采用沉淀法制备了非负载型 Ni 催化剂, 运用 X 射线衍射、H2-程序升温还原及 CH4 程序升温表面反应对催化剂进行了表征, 并考察了 Ni 催化剂上 CH4 分解反应活性. 结果表明, 以乙酸镍为前驱体制得的 NiO 样品粒子尺寸较小, 较易被还原, 还原后得到的催化剂催化 CH4 分解活性和稳定性较高; 而以硝酸镍为前驱体制得的 NiO 样品粒子尺寸较大, 较难被还原, 还原后催化剂上 CH4 分解活性和稳定性较低. 制备过程中乙酸镍与溶剂乙二醇所形成的配合物是获得尺寸较小 NiO 样品的关键.     

Easy Access to Ni3N– and Ni–Carbon Nanocomposite Catalysts

In the search for alternative materials to current expensive catalysts, Ni has been addressed as one of the most promising and, on this trail, its corresponding nitride. However, nickel nitride is a thermally unstable compound, and therefore not easy to prepare especially as nanoparticles. In the present work, a sol–gel‐based process (the urea glass route) is applied to prepare well‐defined and homogeneous Ni₃N and Ni nanoparticles. In both cases, the prepared crystalline nanoparticles (～25 nm) are dispersed in a carbon matrix forming interesting Ni₃N‐ and Ni‐based composites. These nanocomposites were characterised by means of several techniques, such as XRD, HR‐TEM, EELS, and the reaction mechanism was investigated by TGA and IR and herein discussed. The catalytic activity of Ni₃N is investigated for the first time, to the best of our knowledge, for hydrogenation reactions involving H₂, and here compared to the one of Ni. Both materials show good catalytic activities but, interestingly, give a different selectivity between different functional groups (namely, nitro, alkene and nitrile groups).     

Identification of Hydroxyl on Ni(111)

Hydroxyl (OH) is identified and characterized on the Ni(111) surface by high‐resolution electron energy loss spectroscopy. We find clear evidence of stretching, bending, and translational modes that differ significantly from modes observed for H₂O and O on Ni(111). Hydroxyl may be produced from water by two different methods. Annealing of water co‐adsorbed with atomic oxygen at 85 K to above 170 K leads to the formation of OH with simultaneous desorption of excess water. Pure water layers treated in the same fashion show no dissociation. However, the exposure of pure water to 20 eV electrons at temperatures below 120 K produces OH in the presence of adsorbed H₂O. In combination with temperature‐programmed desorption studies, we show that the OH groups recombine between 180 and 240 K to form O and immediately desorbing H₂O. The lack of influence of co‐adsorbed H₂O at 85 K on the O? H stretching mode indicates that OH does not participate in a hydrogen‐bonding network.     

Glycoligands tuning the magnetic anisotropy of Ni(II) complexes

Two organic ligands based on a sugar-scaffold derived from galactose and possessing three O-CH(2)-pyridine pendant arms at the 3-, 4-, and 5-positions of the galactopyranose that act as chelates afford mononuclear complexes when reacted with a Ni(II) salt. The magnetization behavior in the form of M=f(H/T) plots suggests the presence of appreciable magnetic anisotropy within the two complexes. The analysis of the EPR spectra performed at two different temperatures (7 and 17 K) and at three frequencies (190, 285, and 380 GHz) leads to the conclusion that the anisotropy has a high degree of axiality (E/D=0.17 for the two complexes), but with a different sign of the D parameter. The spin hamiltonian parameters D and E were reproduced for the two complexes by using calculations based on the angular overlap model (AOM). The structural difference between the two complexes responsible of the sign of the D parameters was also determined using AOM calculations. A thorough analysis of the structures showed that the structural differences in the coordination sphere of the two complexes responsible of the different D parameter sign result from the nature of the sugar scaffolds. In complex 1, the sugar scaffold imposes an intramolecular hydrogen bond with one of the atoms linked to Ni(II); this arrangement leads to a distorted coordination sphere and positive D value, while the absence of such a hydrogen bond in complex 2 leads to a less distorted environment around the Ni center and to a negative D value.     

The Journey of Ni(I) Chemistry

In the last twenty years, nickel has successfully imprinted its role in the field of homogeneous catalysis as a valid and complementary alternative to palladium and platinum catalysts. However, compared to those, there are often many different available pathways in nickel catalysis due to the facile access of intermediate oxidation states. Among them, Ni(I) has been increasingly proposed as a key oxidation state in multiple transformations. This oxidation state had already been suggested a long time ago but has only recently undergone a renaissance with extensive ligand design which has led to over 100 isolated Ni(I) complexes. In addition, the analysis of many catalytic cycles has revealed that the Ni(I) species can not only occur as a decomposition product perturbing a Ni(0)–Ni(II) pathway but can also play a key role in alternative Ni(I)–Ni(III) cycles. This behavior is highly dependent on the class of transformation and ligand employed in catalysis. Herein, we concisely describe the journey of this oxidation state, combining the information gathered from inorganic synthesis and mechanistic investigations, from its synthesis to its postulated role in different catalytic cycles.     

Ni-Sn-Cr/AC催化剂上乙酸甲酯气相羰基化合成醋酐反应的研究

以活性炭为载体,采用浸渍法制备Ni-Sn-Cr/AC催化剂,在连续流动固定床反应器上研究其对乙酸甲酯气相羰基化合成醋酐反应的催化性能。分别考察了Ni、Sn、Cr三种金属组分的负载量对催化活性的影响,进一步考察了反应压力、反应温度、反应时间对反应的影响。实验结果表明,在Ni9%-Sn12%-Cr6%/AC催化剂上,当反应温度205℃,压力5.5MPa,催化剂焙烧温度600℃,催化剂焙烧时间为4h的条件下,乙酸甲酯的转化率为38.8%,醋酐的选择性为81.1%。采用X射线衍射和元素分析技术分别对反应前和不同反应时间后的催化剂进行了表征。分析结果表明,Ni⁰是催化剂的主要活性中心,随着反应时间的延长,活性组分镍的流失现象比较严重,同时催化剂上出现积炭及载体骨架遭到破坏,是导致催化剂失活的主要原因。     

Ni2P/SiO2 和Ni/SiO2 催化剂甘油氢解反应性能比较:催化剂活性及产物选择性影响因素的探讨（英文）

采用浸渍法及程序升温还原法制备了Ni2P/SiO2和Ni/SiO2催化剂,利用N2吸附-脱附、X射线衍射、X射线荧光、CO化学吸附、氢气程序升温脱附及氨气程序升温脱附等手段对催化剂进行了表征并用于甘油氢解反应.结果表明,Ni2P/SiO2和Ni/SiO2具有相近的表面Ni密度,但前者表面酸中心和表面氢物种(包括吸附氢和溢流氢)密度明显更高,且在甘油氢解反应中的活性也更高,这与其酸性中心与金属中心之间的协同作用有关.Ni2P/SiO2催化剂上主要产物为1,2-丙二醇及1-丙醇,而Ni/SiO2催化剂上主要产物为1,2-丙二醇、乙二醇和乙醇.提高反应温度和H2压力不能促进Ni2P/SiO2上乙醇和乙二醇的生成,但促进了1,2-丙二醇进一步氢解转化为1-丙醇.由此可见,Ni2P/SiO2具有较强的C-O键断裂活性及较弱的C-C键断裂活性,这可能分别与其较多酸性中心和电子及几何结构性质密切相关.     

Determination of Ni with Electrodes Modified with Mordant Violet 5

Abstract

The utility of electrodes modified with the dye Mordant Violet 5 (MV-5) for the determination of Ni is demonstrated. The method is based on the coordination of Ni from solution by an immobilized layer (via ion exchange) of the dye. Upon coordination the redox response of the dye is shifted in the negative direction by about 250 mV (from ?0.74 to ?0.97 V). The height of this peak is used as the analytical signal which is related to the concentration of Ni in solution. Linear calibration curves were obtained for Ni concentrations ranging from about 10^?4 to 2×10^?3M. Although this reflects only moderate sensitivity, a basic concept is established; this method allows for the determination of the metal via the redox response of the dye. Thus, with appropriate choice of reagents, metal ions difficult to determine by direct reduction can be determined by this method. The use of other reagents may result in enhanced sensitivity.