Synergistic effects of bimetallic Cu-Fe/SiO_2 nanocatalysts in selective hydrogenation of diethyl malonate to 1,3-propanediol

Cu-x-Fe-y/SiO2 catalysts were prepared using urea-assisted sol-gel method. The structure and physicochemical properties of the catalysts were characterized using N-2 adsorption-desorption, transmission electron microscopy, H-2-temperature-programmed reduction, powder X-ray diffraction, and X-ray photoelectron spectroscopy. Compared with monometallic Cu or Fe catalysts, the bimetallic Cu-x-Fe-y/SiO2 catalysts exhibited enhanced catalytic performance for the selective hydrogenation of diethyl malonate to 1,3-propanediol. The bimetallic catalyst with an optimal Cu/Fe atomic ratio of 2 exhibited the highest activity, which yielded 96.3% conversion to diethyl malonate and 93.3% selectivity to 1,3-propanediol under the optimal reaction conditions. Characterization results revealed that interactions between Cu and Fe contributed to the improvement of diethyl malonate conversion and selectivity to 1,3-propanediol. The X-ray photoelectron spectroscopy results revealed that the addition of appropriate amount of Fe species enhanced the reduction of Cu2+ species, thereby increasing the Cu-0 species on the surface of bimetallic catalyst. It led to a better chemisorption capacity of hydrogen and further promoted of the activation of hydrogen molecule. The ethyl acetate temperature-programmed desorption results indicated that the FeOx species provided the additional adsorption sites for substrate molecules, and they activated the C=O bond. The improved catalytic performance of bimetallic Cu-x-Fe-y/SiO2 catalyst was mainly attributed to the synergistic effect between Cu-0 and FeOx species. (C) 2016 Science Press and Dalian Institute of Chemical Physics, Chinese Academy of Sciences. Published by Elsevier B.V. and Science Press. All rights reserved.

Selective tandem hydrogenation and rearrangement of furfural to cyclopentanone over CuNi bimetallic catalyst in water

Tandem catalysis for the hydrogenation rearrangement of furfural(FA)provides an attractive solution for manufacturing cyclopentanone(CPO)from renewable biomass resources.The Cu-Ni/Al-MCM-41 catalyst was synthesized and afforded excellent catalytic performance with 99.0%conversion and 97.7%selectivity to CPO in a near-neutral solution under 2.0 MPa H2 at 160℃ for 5 h,much higher than those on other molecular sieve supports including MCM-41,SBA-15,HY,and ZSM-5.A small amount of Al highly dispersed in MCM-41 plays an anchoring role and ensures the formation of highly dispersed CuNi bimetallic nanoparticles(NPs).The remarkably improved catalytic performance may be attributed to the bimetallic synergistic and charge transfer effects.In addition,the initial FA concentration and the aqueous system pH required precise control to minimize polymerization and achieve high selectivity of CPO.Fourier transform infrared spectroscopy and mass spectra results indicated that polymerization was sensitive to pH values.Under acidic conditions,FA and intermediate furfuryl alcohol polymerize,while the intermediate 4-hydroxy-2-cyclopentenone mainly polymerizes under alkaline conditions,blocking the cascade of multiple reactions.Therefore,near-neutral conditions are most suitable for minimizing the impact of polymerization.This study provides a useful solution for the current universal problems of polymerization side reactions and low carbon balance for biomass conversion.

Base-free aerobic oxidation of glycerol on TiO_2-supported bimetallic Au–Pt catalysts

The aerobic oxidation of glycerol provides an economically viable route to glyceraldehyde, dihydroxyacetone and glyceric acid with versatile applications, for which monometallic Pt, Au and Pd and bimetallic Au-Pt, Au- Pd and Pt-Pd catalysts on TiO2 were examined under base-free conditions. Pt exhibited a superior activity relative to Pd, and Au-Pd and Pt-Pd while Au was essentially inactive. The presence of Au on the Au-Pt/TiO2 catalysts led to their higher activities （normalized per Pt atom） in a wide range of Au/Pt atomic ratios （i.e. 1/3-7/1 ）, and the one with the Au/Pt ratio of 3/1 exhibited the highest activity. Such promoting effect is ascribed to the increased electron density on Pt via the electron transfer from Au to Pt, as characterized by the temperature-programmed desorption of CO and infra-red spectroscopy for CO adsorption. Meanwhile, the presence of Au on Au-Pt/TiO2, most like due to the observed electron transfer, changed the product selectivity, and facilitated the oxidation of the secondary hydroxyl groups in glycerol, leading to the favorable formation of dihydroxyacetone over glyceraldehyde and glyceric acid that were derived from the oxidation of the primary hydroxyl groups. The synergetic effect between Au and Pt demonstrates the feasibility in the efficient oxidation of glycerol to the targeted products, for example, by rational tuning of the electronic properties of metal catalysts.

Nitrogen-Doped Carbon-Encased Bimetallic Selenide for High-Performance Water Electrolysis

Demand of highly efficient earth-abundant transition metal-based electrocatalysts to replace noble metal materials for boosting oxygen evolution reaction(OER)is rapidly growing.Herein,an electrochemically exfoliated graphite(EG)foil supported bimetallic selenide encased in N-doped carbon(EG/(Co,Ni)Se2-NC)hybrid is developed and synthesized by a vapor-phase hydrothermal strategy and subsequent selenization process.The as-prepared EG/(Co,Ni)Se2-NC hybrid exhibits a core-shell structure where the particle diameter of(Co,Ni)Se2 core is about 70 nm and the thickness of N-doped carbon shell is approximately 5 nm.Benefitting from the synergistic effects between the combination of highly active Co species and improved electron transfer from Ni species,and N-doped carbon,the EG/(Co,Ni)Se2-NC hybrid shows remarkable electrocatalytic activity toward OER with a comparatively low overpotential of 258 mV at an current density of 10 mA cm?2 and a small Tafel slope of 73.3 mV dec?1.The excellent OER catalysis performance of EG/(Co,Ni)Se2-NC hybrid is much better than that of commercial Ir/C(343 mV at 10 mA cm?2 and 98.1 mV dec?1),and even almost the best among all previously reported binary CoNi selenide-based OER electrocatalysts.Furthermore,in situ electrochemical Raman spectroscopy combined with ex situ X-ray photoelectron spectroscopy analysis indicates that the superb OER catalysis activity can be attributed to the highly active Co-OOH species and modified electron transfer process from Ni element.

合金纳米颗粒原子级分散制备的双位点催化剂中单点Ag1对Pd1在炔烃双烷氧羰基化反应中的促进作用

炔烃烷氧羰基化反应是一种原子经济反应,可以生成α,β-不饱和羧酸、二羧羧酸酯及其衍生物.其中,乙炔的双烷氧羰基化产物(丁烯二酸二酯)可通过两段加氢制备1,4-丁二醇,该反应路径对于生产生物可降解材料聚丁二酸丁二醇酯(PBS)具有重要意义.然而,目前广泛应用的均相Pd基催化体系存在催化剂分离困难、金属流失以及需要添加有机膦配体或各种磺酸助剂等问题,这不仅增加了制备成本,还可能引入不必要的杂质.此外,尽管纳米催化剂在催化领域有着广泛的应用,但大多数纳米催化剂在炔烃双烷氧基羰基化反应中仍表现出反应活性低和稳定性差的问题,这限制了其在工业生产中的应用.相比之下,多相单金属点催化剂因其100%的原子利用率和较好的催化活性而备受关注.然而,由于多相单金属点催化剂具有相对简单的结构和配位环境,其应用仍受到一定的限制.为了克服这一难题,合成具有不同金属的双位点催化剂成为了一个研究热点.双位点催化剂有望进一步释放单金属位点催化剂的潜力,提高反应活性和稳定性.然而,尽管双位点催化剂具有巨大的应用前景,但目前仍面临着制备方法的挑战.如何设计并实用可行地制备出具有高效催化性能的双位点催化剂,是当前科研领域亟待解决的问题.本文提出一种由CO/CH3I混合物诱导分散Pd-Ag合金纳米颗粒的处理方法,用于制备Pd1-Ag1/AC双位点催化剂.利用X射线衍射、X射线光电子能谱和高角环形暗场扫描透射电子显微镜等方法对分散过程进行表征.结果表明,在分散过程中,CO和CH3I与金属发生协同作用,通过配位生成一种独特的双核络合物(PdI2(CO)-I2-AgI)结构.这种络合物结构逐一从合金纳米颗粒上剥落,直至完成原子级的分散.乙炔双烷氧羰基化反应结果表明,与单金属Pd1/AC相比,在相同反应条件下,双位点Pd1-Ag1/AC催化剂上的乙炔转化率提高了2倍.同时,在保持丁烯二酸二酯选择性为98%的情况下,该催化剂循环使用10次后催化剂性能未见明显变化.炔烃底物拓展结果表明,Pd1-Ag1/AC的协同作用不仅可以提高催化活性,而且在高位阻存在的情况下可以提高产物的立体选择性,这表明双位点协同促进作用对炔烃双羰基化反应具有良好的普适性.微分吸附量热表征结果证明了通过碘配体桥连的Pd1和Ag1单金属点之间的协同效应可以增强催化剂对乙炔的吸附能力.此外,结合拓展边X射线精细结构等实验结果,对催化剂的结构变化和反应机理进行了进一步的探究.第一性原理计算得到的反应能垒和过渡态结果表明,乙炔吸附是反应的速率决定步骤.与Pd1/AC相比,Pd1-Ag1/AC催化剂在反应决速步上表现出了更低的活化能,这从热力学和动力学两个层面解释了其具有更好催化性能的原因.Bader电荷分析和投影态密度计算的结果表明,由于Ag1位点的引入,使Pd1-Ag1/AC催化剂的电荷转移能力和吸附能力均得到增强.相较于Pd1/AC,Pd1-Ag1/AC具有更低的形成能,表明Ag1位点不仅可以提升催化活性,也可以增强双位点结构的稳定性.因此,在催化反应中,Ag1位点的存在起到了重要的促进作用,使得Pd1-Ag1/AC催化剂表现出更优异的性能.综上,本文制备的双位点Pd1-Ag1/AC催化剂在乙炔双烷氧羰基化反应中表现出较好的催化活性和稳定性,证明了双位点协同效应的重要性,为高效催化剂的设计和应用提供了新的思路.

双金属电催化CO_(2)还原催化剂的合成、表征和机理研究进展

电催化二氧化碳还原反应(CO_(2)RR)是一种将CO_(2)转化为有价值的化学品的有效方法。然而,CO_(2)的转化是一个复杂的过程,涉及2、4、6、8和12等多电子转移步骤。因此,开发高效的催化剂以精确控制CO_(2)转化过程中的电子转移数目具有重要意义。单金属催化剂存在活性位点单一、反应动力学慢、产物选择性低和稳定性不足等缺点。双金属催化剂因其独特的结构和优异的性能而受到广泛关注。通过引入次金属,可以改变催化剂的电子结构,促进新的活性位点的形成,从而优化中间体与活性位点之间的相互作用。因此,本文综述了以炭材料为基底的单原子双金属催化剂和合金、异质结构等非原子级的双金属催化剂以及它们的制备方法、结构表征和催化产物,归纳双金属催化剂的催化机理。最后,提出CO_(2)RR中遇到的挑战并对今后的发展进行展望。

TMCo-O催化剂结构调控及活化PMS降解双酚A的性能研究

随着时代的发展,人类对塑料的高度依赖导致了双酚A(Bisphenol A,BPA)在水资源中重度积累,从而危及人类的身体安全。以过渡金属离子基催化剂活化过硫酸盐的高级氧化技术为处理双酚A的有效手段,通过调控锌、钴元素的掺杂比例,制备出具有金属有机框架结构的前驱体,再通过500℃高温煅烧,合成了锌钴双金属氧化物催化剂。此外,通过调控不同过渡金属掺杂,还制备了MnCo-Co-O和NiCo-Co-O催化剂。通过分析氧化物催化剂对双酚A的降解速率,研究不同锌、钴元素掺杂比例的催化剂及镍、锰元素掺杂的催化剂对过一硫酸盐(PMS)的活化能力,主要研究了不同锌钴元素掺杂比例的复合金属氧化物催化剂Co-Co-O、Zn-Co-O、ZnCo_(2)-Co-O和ZnCo-Co-O的催化性能。其中,锌钴掺杂比例为1∶2的双金属氧化物(ZnCo_(2)-Co-O)催化效果最好,催化效果的优化是基于锌钴离子之间产生的协同效应。同时,还研究了催化剂降解双酚A时的反应机理。结果表明,以羟基自由基(·OH)和单线态氧(^(1)O_(2))为主要降解路径,可实现水体中有机污染物的高效去除。最后,研究了ZnCo_(2)-Co-O双金属氧化物催化剂在不同的阴离子环境下的催化性能,其中Cl^(-)的存在加快了强氧化基团的生成,SO_(4)^(2-)对催化剂不产生显著影响,而CO_(3)^(2-)会与强氧化基团发生不可逆反应而降低体系催化速率。本研究提供了一种新型过硫酸盐催化剂的改性策略,对于高效过硫酸盐催化剂的研发具有重要的意义。

水溶性含钌-铂双金属催化剂催化卤代芳香硝基化合物选择性加氢

考察了水溶性 Ru/ Pt-TPPTS双金属催化剂催化卤代芳香硝基化合物的加氢性能 .实验结果表明 ,在Ru-TPPTS中添加铂或钯后 ,反应活性明显提高 ,尤其是 Ru/ Pt-TPPTS双金属催化剂更表现出显著的双金属协同效应 .在 p H2 =1 .0 MPa,70℃ ,反应 2 h的条件下 ,双金属催化剂 0 .5 0 Ru/ 0 .5 0 Pt-TPPTS催化对 -氯硝基苯加氢生成对 -氯苯胺的反应转化率达到 1 0 0 % .对于取代基和取代位置不同的一些卤代硝基苯加氢 ,该双金属催化剂也表现出很高的催化活性和生成卤代苯胺的选择性 。

水溶性双金属催化剂在硝基化合物加氢反应中的协同效应

For the hydrogenatlon of aromatic nitrocompounds, PdCl2 (TPPTS)2-H2PtCl6 ex-hibited much higher catalytic activity than that of PdCl2(TPPTS)2 or H2PtCl6. The synergic effect can also be observed even if the composition of Pt was 2% (molar ratio). A high selec-tivity for the chloroaniline was obtained in the hydrogenation of nitrochlorobenzene catalyzed by PdCl2 (TPPTS)2 and bimetallic catalyst PdCl2 (TPPTS)2-H2PtCl6.

高分子负载催化剂在硝基苯加氢中的双金属协同效应

高分子负载催化剂在硝基苯加氢中的双金属协同效应＊郦海青廖世健＊＊徐筠余道容（中国科学院大连化学物理研究所，大连１１６０２３）关键词聚乙烯吡咯烷酮，负载型催化剂，双金属催化剂，协同效应，硝基苯，加氢，苯胺在多相催化中，双金属和多金属催化剂是常见的，但在...

Ni_(2)P催化剂电子结构对4,6-DMDBT加氢脱硫活性和选择性的影响

采用XRD、TEM、XPS以及CO红外吸附等手段,系统研究了Fe、Co和Mo对Ni_(2)P电子结构的影响及其对4,6-DMDBT加氢脱硫(HDS)性能的影响。表征结果表明,3种掺杂金属可较好地调整Ni_(2)P位点的电子状态,影响含硫有机化合物在Ni_(2)P位点上的吸附能。HDS性能评价结果发现,HDS本征活性与Ni_(2)P位点的电子结构之间存在火山型关系,使得具有中等电子密度的Co-Ni_(2)P/SiO_(2)因适中的吸附能呈现出最佳的HDS活性。此外,Ni_(2)P的电子缺陷显著促进直接脱硫(DDS)选择性。与Ni_(2)P/SiO_(2)相比,Mo-Ni_(2)P/SiO_(2)中Ni_(2)P具有更多的电子缺陷,展现出更高的DDS选择性,而Fe-Ni_(2)P/SiO_(2)和Co-Ni_(2)P/SiO_(2)中Ni_(2)P因具有更高的电子密度,其DDS选择性更低。

稀土氯化物催化作用下纳米氢化钠对芳基卤化物的还原脱卤

稀土氯化物催化作用下纳米氢化钠对芳基卤化物的还原脱卤＊张源魁廖世健＊＊徐筠余道容（中国科学院大连化学物理研究所，大连１１６０２３）沈琪（苏州大学化学化工学院，苏州２１５００６）关键词催化还原脱卤，稀土氯化物，氢化钠，双金属协同效应有机卤化物的还原脱卤...

高分子负载钯基双金属催化苯胺氧化羰基化反应

芳香族氨基甲酸酯（ＡｒＮＨＣＯ２Ｒ）是制备芳基异氰酸酯（ＡｒＮＣＯ）的重要中间体，其合成通常需用光气与芳胺反应，且生成大量ＨＣｌ．因此，人们致力于发展一些无需光气参与的反应过程，如催化芳胺氧化羰基化生成芳氨基甲酸酯．Ｐｄ、Ｐｔ、Ｒｈ、Ｉｒ、Ｒｕ等金属...

担载双金属催化剂对Heck反应的作用

制备了0.5%Pd/C催化剂和含钯担载双金属催化剂3%Cu-0.5%Pd/C,3%Mo-0.5%Pd/C,3%Ni-0.5%Pd/C,3%Co-0.5%Pd/C,3%Mn-0.5%Pd/C,用XRD法和XPS法进行了表征。结果表明,室温下,以KBH4还原剂制备的含钯担载双金属催化剂,在碘苯与丙烯酸的Heck偶合反应中,催化活性高于Pd/C(0.5 h的转化率高,完成反应所需时间少),显示出添加贱金属的协同效应。其中,3%Mo-0.5%Pd/C显示出最高的催化活性,在0.5 h时的转化率(67.4%)和收率(52.6%)比0.5%Pd/C分别高54.5%和42.2%,完成反应的时间最短,表明钼的协同效应最高。

1-辛烯在Co/CNTs催化剂上的氢甲酰化研究:钌的促进作用

采用等体积浸渍法制备了碳纳米管负载的钴及钴-钌双金属催化剂,并以1-辛烯的氢甲酰化反应为探针,研究了所制催化剂的催化性能;用TEM、XRD、TPR、TG技术对催化剂的形貌、物相结构、还原行为和热稳定性进行了研究。结果表明,金属钌能够促进金属钴在碳纳米管上的均匀担载,并有助于金属钴的还原,降低了催化剂的还原温度。1-辛烯的氢甲酰化反应结果表明,少量钌的加入,可明显提高反应的转化率和C9-醛的选择性;在双金属催化剂中,金属催化剂的粒径更小,分布更均匀,钌的加入对钴金属催化剂有促进作用。

金-银双金属纳米簇@多壁碳纳米管-二氧化钛纳米材料为新型氧化还原探针构建电化学免疫传感器

该研究合成了具有独特“珍珠项链”结构的金-银双金属纳米簇@多壁碳纳米管-二氧化钛纳米复合材料(Au-Ag NCs@CNTs-TiO_(2)NPs)作为信号标签、载体和信号放大器,构建了一种高灵敏“三明治”式电化学免疫传感器用于糖类抗原19-9(CA19-9)的检测。首先将具有过氧化物模拟酶特性的磁性Au-Fe_(3)O_(4)NPs用于修饰电极,然后通过化学键合作用将anti-CA19-9抗体和BSA固载于电极表面,再通过特异性反应结合不同浓度的抗原和具有氧化还原活性和放大作用的Au-Ag NCs@CNTs-TiO_(2)NPs/Ab_(2)/BSA生物耦合物形成夹心免疫结构进行检测。结果表明,通过双重过氧化物模拟酶催化底液中的H_(2)O_(2),有效地放大了响应信号,在最优条件下,CA19-9在0.01~200 U/mL浓度范围内线性关系良好,最低检出限为0.003 U/mL。采用标准加入法测得免疫传感器的回收率为94.6%~105%,相对标准偏差(RSD)为4.3%~6.5%,表明该免疫传感器有望用于临床血清样品中CA19-9的检测。

水体中芴的催化降解研究

多环芳烃(PAHs)是一类难降解性,致癌、致畸、致突变且易在生物体内富集的持久性有机污染物(POPs),它广泛存在于大气、水、动植物和土壤中。本研究选取多环芳烃中芴作为研究对象,通过正交实验优化纳米Fe-Ni双金属添加量、初始浓度、p H值及温度,寻找芴的最佳去除条件。实验结果表明:当纳米Fe-Ni双金属添加量为3 g/L、芴初始浓度为0.5 mg/L、温度为30℃、p H为5的条件下,去除效果最好,去除率可达到96.2%。

选择氧化物载体调变乙醇重整和1,3-丁二烯加氢反应双金属催化剂(英文)

研究了不同载体负载的Pt-Ni双金属和单金属催化剂上乙醇重整和1,3-丁二烯加氢反应性能, 以考察氧化物载体对双金属结构和催化活性的影响. 所用的氧化物载体包括γ-Al2O3, SiO2, TiO2, CeO2以及高比表面积(HSA)和低比表面积(LSA)ZrO2. 采用共浸渍法制备催化剂, 用CO化学吸附、透射电镜和扩展X射线吸收精细结构光谱进行催化剂表征, 采用傅里叶变换红外间歇反应器进行化学反应评价. 对于乙醇重整反应, Pt-Ni双金属催化剂优于单金属催化剂, Pt-Ni双金属催化剂活性顺序为TiO2>SiO2>-Al2O3≈LSA-ZrO2>CeO2>HSA-ZrO2. 对于1,3-丁二烯加氢反应, 在SiO2,TiO2和HSA-ZrO2载体上双金属催化剂优于单金属催化剂, Pt-Ni双金属催化剂活性顺序为SiO2>CeO2>-Al2O3>LSA-ZrO2>HSA-ZrO2≈TiO2.

负载型双组分催化剂的研究——Ⅲ.Pt-Bi/P催化剂中金属与载体以及金属与金属之间的相互作用

本文研究了负载型双组分催化剂Pt-Bi/P中金属与载体以及金属与金属之间的相互作用,并从理论上作了较为详细的讨论。

水溶性钌-钯双金属催化剂催化卤代芳香硝基化合物选择性加氢

考察了水溶性Ru/Pd-TPPTS双金属催化剂催化卤代芳香硝基化合物的加氢性能.实验结果表明,在原位合成的Ru-TPPTS催化体系中添加PdC l2后,催化剂的活性明显提高,尤其是0.50Ru/0.50Pd-TPPTS双金属催化剂表现出显著的钌和钯之间的双金属协同效应.在PH2=1.0 MPa,70℃,反应70 m in的条件下,双金属催化剂0.50 Ru/0.50 Pd-TPPTS催化对-氯硝基苯中硝基选择性加氢反应时转化率达到100%,生成对-氯苯胺选择性为92.3%.对于取代基和取代位置不同的一些卤代硝基苯加氢,双金属催化剂0.50 Ru/0.50 Pd-TPPTS也表现出很高的催化活性和较高的生成卤代苯胺选择性.