杂多酸盐在Raney Ni和Raney Co表面上的状态

采用XPS表面分析技术研究了Cu3/2PMo12O40改性Raney Ni和Raney Co的表面状态,结果表明,RaneyNi和Raney Co表面上的Cu3/2PMo12O40分子中的Cu2+和Mo6+发生了很大变化,Cu2+被还原为Cu0,而Mo6+被部分还原为Mo5+和Mo4+.这些变化可归因于Raney Ni和Raney Co在制备过程中表面吸附的活泼氢所致.由于Raney Ni表面吸附的氢比Raney Co表面吸附的氢的活性高,使得Raney Ni表面的Mo6+被还原到Mo5+和Mo4+的量多.混合价态Mo的存在提高了羰基在催化剂表面吸附和活化的能力,同时Cu0的存在有助于羰基的加氢反应.所以,混合价态的Mo和Cu0对羰基加氢起着协同的作用.

High yield production of 1,4-cyclohexanediol from lignin derived2,6-dimethoxybenzoquinone via Raney Ni Mn catalyst in hydrogen free conditions

Transformation of lignin to valuable chemicals via sustainable pathways is recognized as one of the most efficient ways to explore its value and replace the nonrenewable petroleum resource. In this work, an environmental-friendly transfer hydrogenation process has been developed to convert lignin derived2,6-dimethoxybenzoquinone to 1,4-cyclohexanediol. Compared with previous work under hydrogen pressure(30 bar), this process uses isopropanol as both solvent and hydrogen donor, which significantly simply the operation process. The core of this study is the design and preparation of Mn modified Raney Ni catalysts by ball milling process. A series of Raney Ni Mn catalysts with different ball milling time and Mn content were prepared and investigated. Characterizations by X-ray diffraction(XRD), X-ray photoelectron spectroscopy(XPS), scanning electron microscope(SEM) and transmission electron microscope(TEM) etc. showed that Ni Mn Al alloy was formed during the ball milling process and then transformed to Ni Mn alloy after treatment by aqueous Na OH. After optimization, a yield as high as 86.1% could be achieved for 1,4-cyclohexanediol at 200℃ in only 1 h.

低碳醇合成Raney Cu－Co催化剂的研究Ⅰ．反应性能考察

本文在５６３Ｋ、６ＭＰａ及Ｈ＿２／ＣＯ＝２的条件下，考察了Ｃｕ／Ｃｏ比不同的几个ＲａｎｅｙＣｕ－Ｃｏ催化剂的反应性能。结果表明：ＲａｎｅｙＣｕ－Ｃｏ催化剂上ＣＯ加氢产物主要为Ｃ＿１－Ｃ＿６正构醇及Ｃ＿１－Ｃ＿８正构烃。烃和醇产品的分布均符合Ｓｃｈｕｌｚ－Ｆｌｏｒｙ方程。但醇产品的链增长几率（０．３－０．５５）均小于烃产品的值（０．６－０．７５）。Ｃｕ／Ｃｏ比不同的催化剂在进入活性稳定区之前，均经过了一个不尽相同的活性波动区，活性趋于稳定所需时间随Ｃｕ／Ｃｏ比增大而缩短。Ｃｕ／Ｃｏ＝０．３－１．５（原子比）时，就醇收率而言，ＲａｎｅｙＣｕ－Ｃｏ催化剂明显高于共沉淀Ｃｕ－Ｃｏ催化剂，Ｃｕ／Ｃｏ＝０．８（原子比）时，稳定醇收率达０．５７ｇ·ｇ￣（－１）·ｈ￣（－１）。

低碳醇合成Raney Cu－Co催化剂的研究Ⅱ．Cu－Co－Al合金及Raney Cu－Co催化剂的XRD表征

本文对Ｃｕ／Ｃｏ比不同的五个Ｃｕ－Ｃｏ－Ａｌ合金样及其碱抽提产物──ＲａｎｅｙＣｕ－Ｃｏ催化剂的体相结构进行了ＸＲＤ表征。结果表明：Ｃｕ－Ｃｏ－Ａｌ合金由ＣｕＡｌ、ＣｕＡｌ＿２及Ａｌ＿（１３）Ｃｏ＿４三种物相构成。随Ｃｕ／Ｃｏ原子比（０．１７～２３．１）增高，Ａｌ＿（１３）Ｃｏ＿４及ＣｕＡｌ物相逐渐减少，直至消失，ＣｕＡｌ＿２物相产生且逐渐增多。ＲａｎｅｙＣｕ－Ｃｏ催化剂由两种Ｃｕ－Ｃｏ固溶体组成，一种富铜，另一种富钴。Ｃｕ－Ｃｏ固溶体的形成发生于碱抽提或还原过程，含钴物相的存在有利于ＣｕＡ１物相的碱抽提。

Raney镍-质子型离子液体体系催化木质素平台分子加氢脱氧制备烷烃

木质素是生物质组成中唯一的芳香类化合物组分,高效转化木质素制备烷烃对于生物质全组分利用具有重要意义。通过设计合成质子型醇胺类离子液体,并与Raney镍催化剂建立催化体系,考察了其对于木质素衍生酚及醚类化合物加氢脱氧制备环烷烃的反应特性和规律。研究证明,Raney镍协同二乙醇胺三氟甲烷磺酸盐([2-HDEA]OTf)催化体系具有最优的催化木质素衍生酚类和醚类化合物加氢脱氧效果。在反应温度130℃,时间15 h,氢气压力3 MPa条件下,木质素衍生酚类及醚类化合物转化率>99.0%,目标产物环烷烃产率>80.0%。Raney镍催化剂表现出与Rh/C等贵金属相近的催化效果,离子液体阴离子结构(OTf)在催化脱氧过程中起关键性作用。

Raney Cu系催化剂在C_(4)加氢除炔中的性能研究

以Raney Cu催化剂为前体,利用氧化还原反应在催化剂表面掺杂助剂得到Ag-Raney Cu催化剂。采用XRD,SEM,XPS等方法表征了催化剂的组成和形貌,并在两段床反应器上研究了所制备催化剂的C_(4)选择加氢除炔能力。实验结果表明,在两段床反应器中、反应温度45℃、LHSV=10 h^(-1)、反应压力1.0 MPa条件下,Raney Cu催化剂具有很高的催化活性,可在高LHSV下脱除C_(4)馏分中的炔烃,但丁二烯损失率较高;Ag-Raney Cu催化剂在具有高催化活性的同时,丁二烯损失率下降至4.0%以下。

Electrochemical partial reduction of Ni(OH)_(2) to Ni(OH)_(2)/Ni via coupled oxidation of an interfacing NiAl intermetallic compound for robust hydrogen evolution

Ni-based porous electrocatalysts have been widely used in the hydrogen evolution reaction(HER)in alkaline water electrolysis,and the catalysts are produced by selective leaching of Al from Ni-Al alloys.It is well known that chemical leaching of Ni-Al intermetallic compound(IMC)generates a high surface area in Ni(OH)_(2).However,the Ni(OH)_(2) produced by leaching the Ni-Al intermetallic compound retards the hydrogen evolution reaction,which is attributed to its weak hydrogen adsorption energy.In this study,we controlled the chemical state of Ni using plasma vapor deposition(PVD)followed by heat treatment,selective Al leaching,and electrochemical reduction.X-ray diffraction(XRD),scanning microscopy(SEM),transmission electron microscopy(TEM),and energy-dispersive X-ray spectroscopy(EDS)were used to confirm the phase evolution of the electrocatalysts during fabrication.We reveal that the heat-treated Ni-Al alloy with a thick Ni2Al3surface layer underwent selective Al leaching and produced biphasic interfaces comprising Ni(OH)_(2) and NiAl IMCs at the edges of the grains in the outermost surface layer.Coupled oxidation of the interfacing NiAl IMCs facilitated the partial reduction of Ni(OH)_(2) to Ni(OH)_(2)/Ni in the grains during electrochemical reduction,as confirmed by X-ray photoelectron spectroscopy(XPS).An electrocatalyst containing partially reduced Ni(OH)_(2)/Ni exhibited an overpotential of 54 mV at 10 mA/cm^(2) in a half-cell measurement,and a cell voltage of 1.675 V at 0.4 A/cm2for single-cell operation.A combined experimental and theoretical study(density functional theory calculations)revealed that the superior HER activity was attributed to the presence of partially reduced metallic Ni with various defects and residual Al,which facilitated water adsorption,dissociation,and finally hydrogen evolution.

Combinatorial Interpretation of Raney Numbers and Tree Enumerations

A new combinatorial interpretation of Raney numbers is proposed. We apply this combinatorial interpretation to solve several tree enumeration counting problems. Further a generalized Catalan triangle is introduced and some of its properties are proved.

Intrinsic kinetics of catalytic hydrogenation of 2-nitro-4-acetylamino anisole to 2-amino-4-acetylamino anisole over Raney nickel catalyst

The catalytic hydrogenation of 2-nitro-4-acetylamino anisole(NMA)is a less-polluting and efficient method to produce 2-amino-4-acetamino anisole(AMA).However,the kinetics of catalytic hydrogenation of NMA to AMA remains obscure.In this work,the kinetic models including power-law model and Langmuir-Hinshelwood-Hougen-Watson(LHHW)model of NMA hydrogenation to AMA catalyzed by Raney nickel catalyst were investigated.All experiments were carried out under the elimination of mass transfer resistance within the temperature range of 70–100°C and the hydrogen pressure of 0.8–1.5 MPa.The reaction was found to follow 0.52-order kinetics with respect to the NMA concentration and 1.10-order kinetics in terms of hydrogen pressure.Based on the LHHW model,the dual-site dissociation adsorption of hydrogen was analyzed to be the rate determining step.The research of intrinsic kinetics of NMA to AMA provides the guidance for the reactor design and inspires the catalyst modification.

Raney Cu催化剂催化草酸二甲酯加氢反应失活与活性再生

以催化草酸二甲酯(DMO)加氢反应失活Raney Cu催化剂中Cu纳米粒子为研究对象,采用TG-DTG、XRD和FT-IR等手段分析其失活及活性再生关键因素,并考察其经原位再生催化剂循环的稳定性能。结果表明,Raney Cu催化剂催化DMO选择加氢反应过程中,催化剂表面积炭覆盖表面活性位,致使表面活性位可逆失效,是其失活的主要原因,而不是催化剂中Cu纳米粒子迁移和聚集烧结。以失活催化剂为基体,经300℃以上热处理能够有效脱除其表面积炭,于适宜条件下催化DMO选择加氢反应,DMO完全转化,乙二醇(EG)收率超过95.0%,而其循环催化稳定时间逐渐缩短。此外,催化剂表面CuC_(2)O_(4)化合物生成、热解引起表面活性物种价态频变诱发结构演化及Cu活性物种不可逆流失,进一步加剧Raney Cu催化剂失活。

Raney镍上松香催化加氢本征动力学

测定在不同类型搅拌器下高压釜的持气量和反应效果 ,认识到松香在Raney镍上催化加氢反应受到外扩散的严重影响 ,利用加入 2 0 0号溶剂油、改造搅拌器类型、提高搅拌速度的方法消除外扩散 ,使反应处于化学动力学控制区 ,然后采集动力学数据 ,经对 17种可能的反应机理模型进行筛选 ,推测的反应机理为 :松香中的主要成分枞酸分子不吸附 ,枞酸分子与催化剂表面上被吸附的氢原子进行反应 ,氢原子的吸附为控制步骤 ,据此导出其本征动力学方程 .

Raney镍上α-蒎烯催化加氢本征动力学

测定在不同类型搅拌器下高压釜的持气量和反应效果,认识到α-蒎烯在雷尼镍上催化加氢反应严重受到外扩散的影响,利用改造搅拌器类型和提高搅拌转速的方法消除外扩散;改变Raney镍的粒度,消除内扩散影响,使反应处于化学动力学控制区,然后采集动力学数据,经对17种可能的反应机理模型进行筛选,认为最可几的反应机理为:催化剂表面上被吸附的氢原子和α-蒎烯分子间的表面反应为控制步骤,据此推导其本征动力学方程。

用超声波技术制备的Raney Ni催化剂及其催化加氢活性

将超声波技术与碱抽滤方法相结合制备出一种RaneyNi催化剂 .以苯饱和加氢为探针反应 ,测定了超声处理时间对RaneyNi催化剂催化活性 (包括吸氢速率和苯转化率 )的影响 .结果表明 ,超声处理对催化剂的活性有明显的促进作用 .随着超声处理时间的延长 ,催化剂的活性先逐渐升高 ,后慢慢降低 ,超声处理 1 5min时可获得最高的催化活性 .通过ICP ,XRD ,XPS ,BET和SEM等手段对RaneyNi催化剂的表面电子态、比表面积、孔体积、孔径、粒径及表面形貌等进行了表征 。

改性Raney Ni催化剂用于加氢合成间苯二甲胺

采用改性RaneyNi催化剂 ,研究了溶剂、温度、压力、催化剂用量对间苯二甲腈 (IPN)加氢合成间苯二甲胺(m XDA)反应的影响。结果表明 ,该催化剂在以甲醇、甲苯为混合溶剂 ,V(甲醇 )∶V(甲苯 ) =1∶2 ,当m(溶剂 )∶m(IPN) =3∶1,反应温度 70℃、压力 6 0MPa～ 7 0MPa、催化剂用量为原料质量的 10 %时 ,IPN转化率接近 10 0 % ,m XDA收率达 97%。失活催化剂经再生 。

制备条件对Raney Cu结构与性能的影响

利用旋铸法制备了快速凝固Cu3 3 .5Al66.5合金 .描述了新型RaneyCu催化剂在制备时的抽提工艺、抽提温度、抽提时间、碱液浓度及合金组成等因素对其结构特征和二乙醇胺脱氢氧化催化性能的影响规律 ,得到了较优化的催化剂制备参数 :采用改进的制备途径 ,合金铝铜比为 2 ,抽提温度为 80℃ ,抽提时间 2h ,碱液浓度为 2 0 %NaOH ;所制备的RaneyCu催化剂具有较高的活性和选择性 ,催化剂重复使用 2 6次后 ,亚氨基二乙酸的转化率≥ 95 % .

新型固定床Raney Ni催化剂的制备、表征及苯加氢活性评价

将镍铝合金粉、拟薄水铝石和田菁粉捏合、成型, 在空气中高温焙烧, 然后用苛性碱溶液充分浸取, 制备出可应用于固定床加氢的活性Raney Ni催化剂. 实验结果表明, 成型合金焙烧过程中, 富铝合金相逐渐转化为贫铝相, 同时小部分金属铝氧化生成αAl2O3, 可提高催化剂的颗粒强度. BET和SEM分析表明, 催化剂表面具有较宽的缝隙和丰富的大孔结构. 苯加氢活性评价表明, 在一定反应条件下, 该新型固定床Raney Ni催化剂活性高于传统负载型镍催化剂, 也高于按照专利方法制备的同类型催化剂.

水介质中催化剂Raney Ni催化2-氯酚加氢脱氯

选择水作为反应介质,以氢气为氢源,研究了Raney Ni催化下、水溶液中2-氯酚的加氢脱氯,调查了溶剂、碱助剂和碱金属或碱土金属氯化物对加氢脱氯反应的影响.发现在水体系中,2-氯酚更容易被加氢脱氯,水作为反应介质时显著改善了加氢脱氯的反应环境,消除了无机氯化物在催化剂表面的吸附和累积,使催化剂保持了高活性.

新型固定床Raney催化剂的制备进展

综述了固定床Raney催化剂的多种制备方法,该类型催化剂主要用于不饱和化合物的加氢反应。Raney催化剂用于固定床连续使用有多种方法,可采用粗Raney合金颗粒,控制活化条件仅溶除合金颗粒外层的金属铝;另外也可将Raney合金粉末添加其他物质成型,或者将适当金属气相沉积于其他材料上,再经高温焙烧、碱液浸取活化后使用,其中后者可以获得形状统一、强度较高、催化活性和活性稳定性较好的固定床Raney催化剂。

新型固定床Raney Ni催化剂的苯加氢活性及耐硫性

将新型固定床Raney Ni催化剂应用于苯加氢反应，研究了反应温度、氢气压力、液态空速、氢与苯的摩尔比及催化剂预处理温度对苯加氢反应的影响，在适宜的条件下进行了200h连续运转，并与负载型Ni催化剂的活性进行了对比。实验结果表明，新型固定床RaneyNi催化剂具有较大的活性金属Ni比表面积，当氢与苯的摩尔比为6：1时，在80～120℃、0．5～1．0MPa、液态空速2．0h^-1的缓和条件下即可实现苯的完全转化。新型固定床Raney Ni催化剂具有较好的耐硫性能，每毫升催化剂可耐受8001μg的硫，远优于负载型Ni催化剂。X射线衍射和扫描电子显微镜-能量色散X射线分析结果表明，硫、氯等杂质吸附中毒及反应温度过高使Ni晶粒聚结是新型固定床Raney Ni催化剂失活的主要原因。

Raney-Cu催化剂的烧结行为

用SSA、PSD、XRD及SEM等实验手段研究了自制Raney-Cu催化剂在不同温度及不同气氛中的烧结行为。发现催化剂表面的烧结分为前后两个不同阶段,各对应于表面上不同孔径的收缩及封堵,催化剂表面的烧结程度与各种气体分子的吸附强度相联系。建立了表面积收缩的动力学方程,对烧结机理进行了探讨。文章指出,烧结行为包括表面及体相两方面的变化。积炭的产生掩盖了铜催化剂表面积的收缩,但加速了体相结晶度的提高。应用量子力学方法计算的烧结起始温度与实验结果吻合较好。