Preparation and characterization of ultrafine Fe-Cu-based catalysts for CO hydrogenation

The ultrafine particles of a new style Fe-Cu-based catalysts for CO hydrogenation were prepared by impregnating the organic sol of Fe（OH）3 and Cu（OH）2 onto the activated Al2O3, in which the organic sol of Fe（OH）3 and Cu（OH）2 were prepared in the microemulsion of dodecylbenzenesulfonic acid sodium（S）/n-butanol（A）/toluene（O）/water with V（A）/V（O） = 0.25 and W（A）/W（S） = 1.50. This catalyst was characterized by particle size analysis, XRD and TG. The results of particle size analysis showed that Fe（OH）3 particles with a mean size of 17.1 nm and Cu（OH）2 particles with an average size of 6.65 um were obtained. TG analysis and XRD patterns suggested that 673 K is the optimal calcination temperature. CO hydrogenation produced C＋OH with a high selectivity above 58 wt% by using the ultrafine particles as catalyst, and the total alcohol yield of 0.250 g·ml^-1 ·h^-1 was obtained when the contents of Al2O3 and K were 88.61 wt% and 1.60 wt%, respectively.

Effect of Cu promoter on Ni-based SBA-15 catalysts for partial oxidation of methane to syngas

A series of Ni/SBA-15 catalysts with 5wt% to 15wt% Ni content as well as a series of 12.5%Ni/Cu/SBA-15 catalysts with 1% to 10% copper content were prepared by the impregnation method. The catalytic performance for partial oxidation of methane was investigated in a continuous flow microreactor under atmospheric pressure. The textural and chemical properties of the catalysts were characterized by XRD, TEM, BET and Hz-TPR techniques. The results indicated that the catalysts modified with Cu promoter showed better performance than those without modification. For the 12.5%Ni/2.5%/Cu/SBA-15 catalyst, at 850 ℃ the conversion of CH4 reached 97.9% and the selectivity of CO and H2 reached 98.0% and 96.0%, respectively. In XRD patterns of the Ni/Cu/SBA-15 catalyst with 7.5 to 10% Cu contents there were CuO characteristic peaks beside NiO characteristic peaks. The mesoporous structure of SBA-15 was retained in all of the catalysts. TPR analysis of the catalysts revealed that a strong interaction between Ni, Cu promoter and SBA-15 support may be existed. This interaction enhanced significantly the redox properties of the catalysts resulting in the higher catalytic activity.

THE XPS STUDY OF Cu-Co BASED CATALYSTS FOR SYNGAS CONVERSION TO ALCOHOLS

The copper-cobalt based catalysts were effective for higher alcohol synthesis, the surface state of the catalysts and the nature of the active sites were investigated by using XPS and XAES spectra, and some strong interactions were also observed, in each of the three cases, (after calcination, after reduction, and during the syngas reaction).

Effect of preparation methods of aluminum emulsions on catalytic performance of copper-based catalysts for methanol synthesis from syngas

Various Cu/ZnO/Al2O3 catalysts have been synthesized by different aluminum emulsions as aluminum sources and their pertormances tor methanol synthesis from syngas have been investigated. The influences of preparation methods of aluminum emulsions on physicochemical and catalytic properties of catalysts were studied by XRD, SEM, XPS,N2 adsorption-desorption techniques and methanol synthesis from syngas. The preparation methods of aluminum emulsions were found to influence the catalytic activity, CuO crystallite size, surface area and Cu0 surface area and reduction process. The results show that the catalyst CN using the aluminum source prepared by addition the ammonia into the aluminum nitrate （NP） exhibited the best catalytic performance for methanol synthesis from syngas.

Development of Cu foam-based Ni catalyst for solar thermal reforming of methane with carbon dioxide

Using solar energy to produce syngas via the endothermic reforming of methane has been extensively inves- tigated at the laboratory- and pilot plant-scales as a promising method of storing solar energy. One of the challenges to scaling up this process in a tubular reformer is to improve the reactor＇s performance, which is limited by mass and heat transfer issues. High thermal conductivity Cu foam was therefore used as a sub-strate to improve the catalyst＇s thermal conductivity during solar reforming. We also developed a method to coat the foam with the catalytically active component NiMg3AlOx. The Cu foam-based NiMg3AlOx performs better than catalysts supported on SiSiC foam, which is currently used as a substrate for solar-reforming cat- alysts, at high gas hourly space velocity （≥400,000 mL/（g.h）） or at low reaction temperatures （≤ 720 ℃）. The presence of a γ-Al2O3 intermediate layer improves the adhesion between the catalyst and substrate as well as the catalytic activity.

湿法制备Cu基Mn-Ce改性甲醇重整制氢催化剂及其催化性能研究

为了提升Cu基催化剂的高温稳定性和使用寿命,并研究过渡金属Mn及轻稀土金属Ce对Cu基甲醇重整催化剂的影响,本文采用新型湿法制备了Cu基Mn-Ce改性催化剂,并在气-固相固定床催化反应装置上评价了其甲醇重整制氢的性能。甲醇转化实验结果显示,Cu基Mn-Ce改性催化剂的甲醇转化率达到98.77%,产出的(H2+CO)含量达到92.5%。高温碳化性能对比实验结果表明,相比未改性的催化剂,Mn-Ce改性催化剂的高温稳定性更强,使用寿命更长。高温碳化后,205℃下的甲醇转化率均在40%以上,未改性催化剂的转化率仅为20%左右。催化剂性能评价实验结果表明,催化反应温度与其制氢性能呈正相关,高温下催化剂有更优异的制氢表现。Mn、Ce的加入可以有效提高Cu基催化剂甲醇重整制氢的性能。

络合剂对固相法Cu/ZnO/In_(2)O_(3)催化剂的CO_(2)加氢制甲醇反应性能的影响

为了促进催化剂中Cu物种的分散,在金属硝酸盐中分别加入草酸、甲酸和柠檬酸,采用固态研磨合成Cu/ZnO/In_(2)O_(3)催化剂.结果表明:草酸的加入对Cu的分散效果最好,在280℃,2 MPa,3.6 L·gcat^(-1)·h^(-1),V(H2)∶V(CO_(2))=3∶1时,甲醇收率最高,达到2.1 mmol·gcat^(-1)·h^(-1).但甲酸在高温下会分解为CO_(2)和H_(2),导致制备的CuO/ZnO/In_(2)O_(3)催化剂部分还原,随后此催化剂在H_(2)预处理后被过度还原,形成Cu_(3)In_(7)合金相,导致甲醇产率降低.

多孔聚噻吩聚合物负载Cu-Cu_(2)O纳米颗粒高效催化醇氧化

通过噻吩的氧化偶联反应,制得富含N、S杂原子的多孔有机聚合物PTPA。然后利用溶剂热法,合成了PTPA负载Cu-Cu_(2)O的复合材料Cu-Cu_(2)O/PTPA,并通过红外光谱(IR)、X射线衍射(XRD)、热重分析(TGA)、N_(2)吸附-脱附、X射线光电子能谱(XPS)、扫描电镜(SEM)和高分辨透射电镜(HRTEM)等对其进行了全面表征。在30℃空气中的温和条件下,以2,2,6,6-四甲基哌啶氧化物(TEMPO)为助催化剂和N-甲基咪唑(NMI)为辅助配体,Cu-Cu_(2)O/PTPA对苄醇、烯丙醇及杂环醇表现出良好的选择性催化氧化性能。这归因于该材料富含N、S杂原子,Cu-Cu_(2)O/PTPA在催化苯甲醇氧化方面表现出优异的循环稳定性,重复使用9次后仍保持97%以上的产率。

CuO/γ-Al_(2)O_(3)/SiO_(2)催化剂制备及其苯酚废水催化降解性能

以拟薄水铝石、SiO_(2)微球颗粒和纳米CuO为原料,经有机溶剂分散粘结、相转化和焙烧成型制备了CuO/γ-Al_(2)O_(3)/SiO_(2)负载型催化剂。采用SEM,XRD,BET和ICP对负载型催化剂进行表征和组成分析。在不同浓度、pH、温度和盐浓度下,测试了负载型催化剂对废水中难降解酚类物质的催化氧化效果。经60℃下2 h催化氧化处理后,100 mg/L COD的苯酚降解率可达81.79%,出水COD低至19.00 mg/L,因而可应用难降解废水处理。

制备方法对Cu/Ce_(0.8)Zr_(0.2)O_(2)催化剂催化甲醇水蒸气重整制氢性能的影响

制备方法会影响催化剂中Cu物种种类、分散性及其与载体之间的相互作用。分别采用沉积沉淀法、氨蒸法、浸渍法和共沉淀法制备了以Ce_(0.8)Zr_(0.2)O_(2)固溶体为载体、Cu负载量(质量分数)为15%的Cu/Ce_(0.8)Zr_(0.2)O_(2)催化剂。采用XRD、N_(2)物理吸/脱附、N_(2)O滴定和SEM等对催化剂的物相组成、织构性质、Cu分散度和微观结构等进行了表征,并采用固定床反应器评价了催化剂的甲醇水蒸气重整制氢催化性能。结果表明,与其他3种方法制备的Cu/Ce_(0.8)Zr_(0.2)O_(2)催化剂相比,采用沉积沉淀法制备的Cu/Ce_(0.8)Zr_(0.2)O_(2)催化剂(Cu/Ce_(0.8)Zr_(0.2)O_(2)-DP)具有相对最大的比表面积(82.5 m^(2)/g)和Cu比表面积(206.0 m^(2)/g),以及相对最高的Cu分散度(30.5%)。在温度为250℃、常压、n(去离子水):n(甲醇)为1.3:1.0和液时空速为6 mL/(g·h)的条件下反应24 h,Cu/Ce_(0.8)Zr_(0.2)O_(2)-DP表现出相对最优的催化性能,其甲醇转化率为95.2%,产氢速率为286.8 mmol/(g·h),CO选择性为0.86%。

UiO-66-NH_(2)负载铜催化剂的制备及其对醇的催化氧化

通过溶剂热法成功制备了一种基于金属有机骨架(MOF)的复合材料Cu-Cu_(2)O/UiO-66-NH_(2),采用傅里叶变换红外光谱(FTIR)、X射线衍射(XRD)、扫描电子显微镜(SEM)、透射电子显微镜(TEM)、X射线光电子能谱(XPS)对材料进行全面表征。在空气作氧化剂条件下,以苯甲醇氧化为苯甲醛作为模型反应,系统地考察了溶剂、温度、催化剂各组分用量等因素对催化效果的影响。研究结果表明,该复合催化剂在醇选择性氧化反应中表现出优异的催化性能,60℃下反应5 h便可将苯甲醇定量转化为苯甲醛,并对其他苄基醇、烯丙基醇和杂芳基醇等底物也展现出良好活性。此外,循环利用3次后,该催化剂活性几乎不变,表明其具有良好的稳定性和重复使用性。

助剂添加对CuO/TiO_(2)催化剂NH_(3)-SCO性能的影响研究

采用浸渍法制备了一系列CuO-MO_(x)/TiO_(2)(M=W,Zr,La)催化剂用于NH_(3)选择性催化氧化(NH_(3)-SCO),同时探究了SO_(2)中毒对NH_(3)氧化性能的影响.结果表明,过渡金属氧化物的添加使Cu/TiO_(2)催化剂NH_(3)转化率降低,但显著提高N_(2)选择性.其中,W03具有最好的促进效果,在300℃下催化剂N_(2)选择性提高了36%.通过H_(2)-TPR和NH_(3)-TPD表征发现,WO_(3)的添加增加了Cu/TiO_(2)催化剂表面酸性位点的数量,促进NH_(3)的吸附,但降低催化剂氧化还原性能,抑制NH_(3)氧化为NOx.经SO_(2)中毒处理后,CuO-MO_(x)/TiO_(2)催化剂N_(2)选择性进一步提高,表征结果表明,酸性位点的增加和氧化氧化还原性的降低是提高催化剂N_(2)选择性的关键.

Cu基催化剂催化CO_(2)加氢研究进展

二氧化碳(CO_(2))的捕集与利用是实现“双碳”目标的重要技术手段,其中CO_(2)催化加氢不仅可以减少碳排放,还能将其转化为甲醇等高价值的化工产品。催化剂和反应器设计是CO_(2)催化加氢的关键,其中,Cu基催化剂是最为常用的催化剂。本文针对CO_(2)催化加氢现状,归纳了CO_(2)催化加氢的基本原理,重点从Cu基催化剂的结构特性与催化机制、催化反应器等综述了CO_(2)催化加氢研究进展,并展望了今后的发展方向。

Cu/AC催化湿式氧化降解苯酚废水性能研究

以前驱体浸渍法制备铜基碳材料(Cu/AC)为催化剂,考察固定床反应器中不同操作条件对催化湿式氧化(CWAO)降解苯酚性能的影响。利用N_(2)-吸附脱附、XRD、XPS、热重技术,对反应前后Cu/AC结构进行表征,探究Cu/AC失活原因。结果表明,Cu/AC催化CWAO反应的最优操作条件为反应温度180℃,反应压力3.0 MPa,液时空速15 mL(g·h),气时空速4.5 L/(g·h),在反应5 h时苯酚、化学需氧量(COD)转化率分别达到97.0%、89.4%。Cu/AC催化剂失活的原因主要为Cu组分流失和表面沉积物的生成。反应过程中,Cu^(+)和Cu^(0)被氧化为更易流失的Cu^(2+),导致Cu组分流失,降低催化活性;此外,部分中间产物沉积在Cu/AC表面,造成催化剂孔道堵塞,暴露的活性位点减少,使得催化活性进一步降低。

二氧化碳加氢制甲醇Cu基催化剂疏水改性研究进展

综述Cu基催化剂研究现状和二氧化碳加氢制甲醇的反应机理,分析在二氧化碳反应过程中水对催化剂的影响,从催化剂组分、微观结构以及反应装置设计等方面阐述Cu基催化剂耐水热稳定性的改性技术,并指出优化制备工艺、调控反应工艺、开发疏水改性技术、开发新型反应器等是解决Cu基催化剂失活的改进方向。

助剂Cu、K对F-T合成铁基催化剂作用的表征研究

采用连续共沉淀和喷雾干燥技术相结合的方法制备了一组Cu、K助剂单独或同时加入的微球状Fischer-Tropsch(F-T)合成铁基催化剂,借助低温N2 吸附、MES、XRD、H2 -TPR、CO-TPR研究了Cu和K助剂对催化剂织构、还原性能以及还原和炭化过程中的物相变化的影响。结果表明,K助剂的加入能明显提高催化剂的比表面积和铁物相在催化剂中的分散程度,增加了Fe2O3 与SiO2 间的相互作用;当催化剂在H2 和合成气中还原时,Cu助剂的加入有利于催化剂的还原和Fe3O4 的生成,在CO中还原时,Cu助剂的加入则有利于α-Fe的生成和稳定化。在H2 和合成气中,单独K助剂的加入会抑制催化剂的还原或炭化,而Cu和K助剂的同时加入在H2、CO和合成气下均可使催化剂的还原或炭化能力明显提高,表明Cu和K助剂间存在一定的协同作用。

碱金属对CO加氢制备低碳醇Cu-Fe-Co基催化剂的影响

考察了碱金属(Li、Na、K、Cs)对CO加氢制备低碳醇Cu-Fe-Co基催化剂反应性能的影响。研究发现:碱金属的添加能明显降低甲烷化反应,提高催化剂活性,使醇分布向碳链增长方向转移;碱金属Na的添加对催化剂活性的提高影响最大,与未添加碱金属的催化剂相比,液体产物中总醇质量分数提高45.98%,其中C2+醇和C5+醇在总醇中的摩尔分数分别提高了21.88%和22.89%,尾气中CH4摩尔分数下降42.83%。XRD结果表明,碱金属的加入使Cu、Fe、Co三种组分在载体上分散性加强,增加了CO与活性组分的接触位点从而使碳链增长;FE-SEM结果表明,碱金属Na的添加提高了催化剂孔隙结构和活性组分的均匀性和稳定性,同时减轻了催化剂积炭现象,提高了醇收率。

Al_2O_3-ZrO_2复合氧化物对Cu基催化剂选择加氢性能的影响

采用共沉淀法制备Al2O3-ZrO2复合氧化物,并以此为载体制备负载型Cu基催化剂,运用X射线衍射、X射线能谱、扫描电子显微镜对载体和催化剂进行表征。以糠醛气相加氢制糠醇反应为探针,考察复合氧化物对Cu基催化剂选择加氢活性的影响。结果表明,Al2O3-ZrO2复合氧化物中ZrO2的存在会减少CuO与Al2O3的接触,降低Cu基催化剂的深加氢能力;Al2O3有助于延迟ZrO2的晶化,避免活性组分Cu嵌入到ZrO2晶格中导致催化活性下降。载体中ZrO2质量分数为20%时,Cu/Al2O3-ZrO2催化剂选择加氢活性最高,与Cu/Al2O3催化剂相比,该催化剂具有较好的低温加氢活性和高温加氢选择性。

Cu-Fe基双孔载体催化剂结构和低碳醇合成反应性能

采用超声浸渍法制备了Cu、Fe双活性组元改性的双孔载体(M)催化剂, 采用N2物理吸附、H2程序升温还原/脱附(H2-TPR/TPD)、X 射线衍射(XRD)等表征手段考察了催化剂中Cu-Fe的相互作用, 并在固定床反应器中评价了Cu/Fe摩尔比的改变对低碳醇合成反应性能的影响. 结果表明: 小孔硅溶胶浸渍在大孔硅凝胶中可形成具有不同纳米孔径结构的双孔载体, 增加小孔硅溶胶的含量可促使双孔载体中小孔纳米结构尺寸变小. Fe/Cu摩尔比的增加有利于铜物种在载体表面的分散, 促进了表层CuO和Fe2O3的还原, 加强了双孔载体内孔道与铜铁氧化物之间的相互作用, 促使了单质铜的分散和铁碳化物的生成. CO加氢反应活性和低碳醇时空收率随着Fe/Cu摩尔比的逐渐增加呈现增加的变化趋势. 当Fe/Cu摩尔比增加到30/20时,Cu-Fe基双孔载体催化剂的CO转化率增加到46%, 低碳醇的时空收率增加到0.21 g·mL-1·h-1, C2+OH/CH3OH 质量比达到 1.96.

Fe、Co组成对Cu-Fe-Co基混合醇催化剂合成性能的影响

采用共浸渍法制备了一系列不同Fe、Co组成的Cu-Fe-Co基混合醇催化剂,对其CO加氢合成混合醇反应性能进行了考察,并采用BET比表面积分析、X射线衍射(XRD)、X射线光电子能谱(XPS)、场发射扫描电子显微镜(FE-SEM)及H_2程序升温还原(H_2-TPR)等手段对其进行了表征.结果表明:Cu-Fe二元催化剂添加适量的Co可以明显提高催化剂醇的明空收率(STY)、CO转化率,而总醇选择性不变.当活性组分Cu、Fe及助剂Co的质量分数分别为25%、22%、3%时,催化剂醇的时空收率高达205.6 g·kg^(-1)·h^(-1),CO转化率为56.6%.XRD、XPS和TPR结果表明:在Cu组分含量不变时,少量Co组分的引入使催化剂表面形成微量的CuFe_2O_4相,促进了Cu-Fe组分间相互作用的增强,改善了催化剂活性组分的分散度,有利于提高催化剂活性及醇的时空收率;随Co含量的增大,催化剂中金属组分间的相互作用发生转变,形成了Cu-Co尖晶石相,导致催化剂的醇选择性有所下降.