制备条件对Ni2P/TiO2-Al2O3催化剂加氢脱硫性能的影响

采用溶胶-凝胶法制备了TiO₂-Al₂O₃复合载体, 以柠檬酸为络合剂, 浸渍法制备了负载型Ni₂P/TiO₂-Al₂O₃催化剂前体, 程序升温H₂还原法制备了Ni₂P/TiO₂-Al₂O₃催化剂, 并用 X 射线衍射(XRD)、N₂吸附比表面积(BET)测定技术对催化剂的结构和性质进行了表征, 考察了浸渍方法、Ni/P摩尔比、Ni₂P负载量对其进行的二苯并噻吩(DBT)加氢脱硫(HDS)性能的影响。结果表明, 当Ni/P比低于1:1时, 能得到单一的Ni₂P物相;当Ni/P比为2:1时, 开始出现Ni₃P物相。采用Ni/P比为1:1、Ni₂P负载量为30%、采用共浸渍方法制备的Ni₂P/TiO₂-Al₂O₃催化剂具有最好的活性, 在360℃、3.0MPa、氢油比500 (体积比)、液时体积空速2.0h^-1的条件下反应4h时, 二苯并噻吩转化率为99.5%。     

La-Ni2P/SBA-15/堇青石整体式催化剂及加氢脱硫性能

以介孔分子筛SBA-15为载体,制备一系列不同La含量的La-Ni₂P/SBA-15催化剂前驱体,将La-Ni₂P/SBA-15前驱体涂覆在预处理的整体式载体堇青石上,在H2气氛程序升温还原,制备不同La含量的La-Ni2P/SBA-15/堇青石整体式催化剂。对合成的催化剂进行X射线衍射和N2吸附-脱附结构表征,并评价对二苯并噻吩的加氢脱硫活性。结果表明,Ni₂P存在于所有的La-Ni2P/SBA-15/堇青石整体式催化剂中,且随着La含量的增加,La-Ni2P/SBA-15/堇青石整体式催化剂的比表面积和孔体积均有一定程度的提高,催化活性也提高。对于Ni2P/SBA-15/堇青石整体式催化剂,在300 ℃和380 ℃时,二苯并噻吩加氢脱硫转化率仅为27.2%和91.3%;而1.5%La-Ni₂P/SBA-15/堇青石催化剂在300 ℃和380 ℃时,二苯并噻吩转化率分别为36.8%和96.3%,显示出较好的二苯并噻吩加氢脱硫活性。La-Ni₂P/SBA-15/堇青石整体式催化剂在对二苯并噻吩的加氢脱硫过程中,以直接脱硫和加氢脱硫两种脱硫方式同时进行,并且以直接脱硫为主。     

Ti对Ni2P催化剂加氢性能的影响

采用共沉淀法制备Ni₂P催化剂及TiO₂改性的Ni₂P催化剂,以1-庚烯的甲苯溶液为模型原料,考察引入不同含量Ti对Ni₂P催化剂加氢性能的影响,对催化剂进行表征,结果表明, Ni₂P催化剂对烯烃基本无加氢活性,引入Ti后可显著提高催化剂加氢性能,Ti与Ni物质的量比为0.03时,1-庚烯完全被加氢转化为烷烃,同时有少量的甲苯溶剂发生化学反应,说明此时催化剂对1-庚烯加氢具有较高选择性,对甲苯加氢活性较低。随着Ti引入量的增加,对1-庚烯加氢活性不断提高;继续增加Ti的引入量,甲苯溶剂损失增大,芳烃收率损失严重。     

Ni2P/SiO2催化剂制备及其乙酸加氢制乙醇催化性能评价

通过等体积浸渍和N₂气流中热处理过程制备了系列氧化硅负载过渡金属磷化物催化剂,经乙酸加氢制乙醇反应实验和动力学分析评价催化剂性能。研究结果表明,随着反应温度从280℃升高到340℃,乙酸转化率和乙醇选择性均逐渐提高。随着催化剂制备的P/Ni摩尔比从2：1增大到4：1,催化剂活性和乙醇选择性均先增大后减小,P/Ni摩尔比为3：1催化剂性能较佳。250℃热处理制备催化剂的催化性能优于200℃及300℃。Ni₂P/SiO₂催化剂活性和乙醇选择性均高于Co₂P/SiO₂催化剂。用次磷酸钠作为磷补充源制备催化剂的性能优于次磷酸钾。采用较佳条件下制备的Ni₂P/SiO₂催化剂,在温度340℃、压力2.0 MPa、氢酸进料量比10：1、质量空速0.4 h^-1条件下进行乙酸加氢反应,乙酸转化率为100%,乙醇选择性达到74.56%,并且适当升高反应温度会进一步提高乙醇选择性。     

焙烧及还原条件对Ni2P/TiO2-Al2O3催化剂加氢脱硫性能的影响

采用溶胶-凝胶法制备了TiO₂-Al₂O₃复合载体, 以柠檬酸(CA)为络合剂采用浸渍法制备了Ni₂P负载的TiO₂-Al₂O₃复合载体催化剂, 并用 X 射线衍射(XRD)、N₂吸附比表面积(BET)测定技术对催化剂的结构和性质进行了表征, 考察了载体焙烧温度、催化剂焙烧温度、还原温度、还原压力对其进行的二苯并噻吩(DBT)加氢脱硫(HDS)性能的影响。结果表明, 升高载体焙烧温度有利于催化剂表面上活性物种的分散, 但焙烧温度过高会导致催化剂烧结, 适宜的载体焙烧温度为550℃。当还原温度为500～550℃时, 磷化镍主要以Ni₁₂P₅相形式存在, 且随着还原温度的升高, Ni₁₂P₅的衍射峰强度逐渐增强, 还原温度为700℃时, 可得到单一的Ni₂P物相。载体焙烧温度为550℃, 催化剂焙烧温度为500℃, 还原温度为700℃, 常压还原制备的Ni₂P/TiO₂-Al₂O₃催化剂具有最好的活性。在360℃、3.0MPa、氢油体积比500、液时体积空速2.0h^-1的条件下, 反应4h时, DBT转化率为99.5 %。     

硼改性大孔M-Ni-P纳米自组装Al2O3加氢催化剂柴油脱硫性能

制备适宜孔容和高比表面积的纳米自组装介孔Al₂O₃载体。对载体进行硼改性,共浸法负载Mo-Ni-P双金属活性组分制备了最可几孔径40.3 nm、比表面积144 m²·g^-1和孔容较大的加氢精制催化剂。采用压汞法和XRD对催化剂进行表征。以孤岛焦化柴油为原料,在固定床反应器上评价新型催化剂的反应活性,结果表明,催化剂适宜加氢条件：温度350 ℃,压力7 MPa,氢油体积比600∶1,体积空速1.5 h^-1,在此条件下,产品脱硫率为96.91%,参比剂脱硫率为97.01%。     

碳化钼催化剂的制备及噻吩加氢脱硫性能

以MoO₃为前躯体,CH₄/H₂为还原碳化气,采用自制的程序升温还原碳化反应装置制备出Mo₂C催化剂,并用XRD、BET进行表征.借助原位TG-DTA方法研究了MoO₃在CH₄/H₂气氛中的还原碳化历程和适宜的还原碳化温度.以噻吩/环己烷溶液为模型反应物,采用高压微反-色谱实验装置考察了制备的碳化钼催化剂的噻吩加氢脱硫反应性能.结果表明：程序升温条件下的局部规整反应可提高催化剂的比表面积,且制备的碳化钼催化剂具有较高的噻吩加氢脱硫反应活性,在体积分数为5%的噻吩/环己烷溶液中,反应压力为3.0 MPa,空速为6 h^-1,H₂/原料液体积比500∶1的反应条件下, 370℃时的噻吩转化率达到98%以上,明显高于相应的硫化钼催化剂.还原碳化终温的提高,导致碳化钼催化剂比表面积的减少和表面积炭的增多,进而使其加氢脱硫反应活性降低.MoO₃在CH₄/H₂气氛中的还原碳化历程应为MoO₃→MoO₂→MoO_xC_y→Mo₂C,实验确定的适宜还原碳化温度为675℃.     

制备条件对Co-Mo/TiO_2-Al_2O_3汽油HDS催化剂性能的影响

以蔗糖为辅助剂,采用溶胶-凝胶法制备了介孔氧化铝及相应的Co-Mo/TiO2-Al2O3汽油脱硫催化剂,并对其进行了TEM、XRD和N2吸附表征。以FCC汽油重馏分为原料,重点考察了不同条件下制得的Al2O3对催化剂选择性加氢脱硫性能的影响。结果表明,蔗糖(sucrose)添加量和pH值对Al2O3织构产生影响,进而影响到对应催化剂的加氢脱硫性能;在Al/sucrose摩尔比1∶1、pH值5.4时Al2O3的比表面积最大、孔径分布最窄,对应催化剂的选择性加氢脱硫活性最好;Al2O3的最可几孔径随pH值的增加而增大;溶胶老化温度对Al2O3的比表面积和孔容影响较大,但对最可几孔径和孔径分布影响较小。与Co-Mo/TiO2-sAl2O3(以sAl2O3表示市售Al2O3)催化剂相比,Co-Mo/TiO2-Al2O3催化剂具有较好的选择性加氢脱硫活性,在考察的条件范围内,脱硫率相同时其对应的烯烃饱和度低5%～15%左右。     

Au-Pd/TiO2-Al2O3催化剂的加氢脱硫性能研究

采用溶胶凝胶(sol-ge1)、共沉淀(CP)和沉积沉淀(DP)法制备了介孔TiO2-Al2O3复合载体(简称复合载体);以噻吩加氢脱硫(HDS)为探针反应,考察了复合载体制备条件对负载型Au-Pd催化剂噻吩HDS反应性能的影响;并采用X射线衍射进行表征.结果表明,不同温度焙烧的TiO2一Al2O3复合载体都具有介孔结构,其中773 K焙烧制得的TiO2一Al2O3复合载体的比表面积和孔容较大,B酸中心较多;以乙醇还原的Au-Pd/TiO2-Al2O3催化剂的加氢脱硫活性较好.乙醇还原的Au-Pd/TiO2-Al2O3催化剂中Au-Pd之间及活性组分与载体之间的相互作用较强,形成AuxPdy合金的晶粒较小,活性组分的分散度和活性表面积较大,反应活化能较低,这些均有利于催化剂活性的提高.     

TiO2-SiO2复合氧化物载体及其加氢脱硫催化剂

分别采用溶胶-凝胶法和共沉淀法制备了TiO2-SiO2复合氧化物,并以此复合氧化物为载体制备了加氢脱硫催化剂.采用氮气恒温吸附脱附、X射线衍射、傅立叶变换红外光谱(FT-IR)和NH3程序升温脱附实验(NH3-TPD)对TiO2-SiO2复合氧化物及其催化剂进行表征,并考察催化剂的加氢脱硫性能.结果表明,TiO2经SiO2复合改性后,其热稳定性和晶相稳定性得到了提高.溶胶-凝胶法与共沉淀法相比,能使Ti物种和Si物种混合得更均匀,从而有利于制得具有较大比表面积和孔容的TiO2-SiO2复合氧化物.Ti含量增加,复合氧化物中Ti的分散度会降低.TiO2-SiO2复合氧化物中以Lewis酸中心为主,共沉淀法制备的复合氧化物比溶胶-凝胶法制备的复合氧化物具有更多的酸性中心.具有较大比表面积和较高酸性的催化剂对模型化合物噻吩和锦西重油催化裂化柴油的加氢脱硫性能较高.     

Ni2P/ZrO2催化剂对苯酚的加氢性能

采用浸渍法及热分解法合成了不同负载量的Ni₂P/ZrO₂催化剂,通过XRD、TEM和氮气吸脱附等多种手段表征其物理化学性质,并通过对苯酚的加氢处理来研究载体对Ni₂P活性的影响。结果表明：Ni₂P分散负载在ZrO₂的表面,ZrO₂载体降低了Ni₂P的粒径,有效防止了Ni₂P的聚集,显著提高了Ni₂P对苯酚加氢脱氧的活性。在相同催化条件下,10%-Ni₂P/ZrO₂呈现出最佳催化活性。以10%-Ni₂P/ZrO₂为代表考察催化反应最优条件,在反应温度300℃、初始氢气压5MPa下反应2h,苯酚转化率达到90.8%,环己烷选择性达到91.7%。     

磷化法制备Ni x P y 及其复合材料光解水性能

磷化镍具有Ni₃P、Ni₁₂P₅、Ni₂P、Ni₅P₄等多种晶相,深入研究各个晶相的制备规律和稳定存在条件对开发磷化镍基催化材料至关重要。本文系统考察了磷化时间、磷化温度、Ni/P摩尔比、磷化气速和磷源种类对制备晶相的影响。结果发现,以Ni₃P为前体、红磷为磷源时,可以得到Ni₅P₄、Ni₂P、Ni₁₂P₅三种晶相;以次磷酸盐为磷源时只能得到Ni₂P和Ni₁₂P₅晶相。当以红磷为磷源时,反应温度是影响晶相的主要因素,磷化温度为500℃、600℃和800℃时分别得到Ni₅P₄、Ni₂P和Ni₁₂P₅晶相。将制备的Ni₃P、Ni₂P、Ni₁₂P₅和Ni₅P₄作为助剂,与CdS复合制备光催化复合材料,得到的4种Ni _x P _y /CdS复合材料均表现出良好的光解水制氢性能,Ni₅P₄/CdS表现出最优的产氢能力,为CdS的5.4倍。表征结果证明,引入Ni _x P _y 能够有效抑制反应过程中CdS的载流子复合,提升其光解水反应活性。     

Synthesis of dypnone using SO4/Al-MCM-41 mesoporous molecular sieves

The mesoporous molecular sieves Al-MCM-41 with Si/Al ratio equal to 16, was synthesized under hydrothermal conditions using cetyltrimethylammonium bromide (CTMA⁺Br⁻) as surfactant. The same ratio of Al-MCM-41 materials was impregnated using sulfuric acid, the materials as sulfated Al-MCM-41 (SO₄²⁻/Al-MCM-41). The mesoporous materials viz Al-MCM-41 and SO₄²⁻/Al-MCM-41 were characterized using several techniques e.g. ICP-AES, Nephelometer, XRD, FT-IR, TG/DTA, N₂-adsorption, solid-state-NMR, SEM and TPD-pyridine. ICP-AES studies indicated the presence of Al in the mesoporous materials. Nephelometer studies indicated the SO₄²⁻ presence of the SO₄²⁻/Al-MCM-41. XRD studies indicated that the calcined materials of Al-MCM-41 and SO₄²⁻/Al-MCM-41 had the standard MCM-41 structure. The surface area, pore diameter, pore volume and wall thickness of the mesoporous materials were calculated by BET and BJH equations, respectively. Crystallinity, surface area, pore diameter and pore volume of SO₄²⁻/Al-MCM-41 decreased except wall thickness and the expelling aluminum from the Al-MCM-41 framework increased the Lewis acidity. FT-IR studies indicated that Al-ions were incorporated in the hexagonal mesoporous structure of Al-MCM-41 and sulfuric acid was impregnated into hexagonal Al-MCM-41 materials. The thermal stability of as-synthesized Al-MCM-41 materials and SO₄²⁻/Al-MCM-41 materials were studied using TG/DTA. The environments of the Al-ions coordinated in the silica matrix were determined by ²⁷Al-MAS-NMR. The morphology of Al-MCM-41 and SO₄²⁻/Al-MCM-41 was determined by SEM. The total acidity of Al-MCM-41 and SO₄²⁻/Al-MCM-41 materials was determined by TPD-pyridine. The catalytic results were compared with those obtained by using sulfuric acid, amorphous silica–alumina, H-β, USY and H-ZSM-5 zeolites. The SO₄²⁻/Al-MCM-41 catalyst exclusively forms the product of dypnone from self-condensation of acetophenone molecules due to higher number of Lewis acid sites and has much higher yields than other catalysts except USY.     

磷化镍催化异丁烷临氢脱氢制异丁烯

以SiO₂为载体,结合浸渍法和程序升温还原法制备磷化镍催化剂,考察了不同n(Ni)/n(P)和不同Ni负载量等对催化剂的结构及异丁烷脱氢性能的影响。运用透射电镜(TEM),X射线衍射(XRD),程序升温还原(H₂-TPR),氢气程序升温脱附(H₂-TPD)等表征手段考察催化剂的组成与结构、还原性能及氢吸附性能。研究结果表明:Ni/P比对催化剂表面的物相有较大影响,n(Ni)/n(P)为1.0和0.5时,形成Ni₂P相;n(Ni)/n(P)为1.5时,形成Ni₁₂P₅。随着Ni负载量的增加,活性组分Ni₂P粒子尺寸变大,但分散度降低。磷化镍能够催化异丁烷脱氢制异丁烯,但Ni₂P的催化活性要比Ni₁₂P₅高,经实验研究发现,当Ni/P比为1.0、负载量为10%、n(H₂)/n(i-C₄H₁₀)=1.0、空速为800 h^-1时,在460 ℃反应时,对异丁烯的选择性可达到80%。     

Ternary Ni2P/Bi2MoO6/g-C3N4 composite with Z-scheme electron transfer path for enhanced removal broad-spectrum antibiotics by the synergistic effect of adsorption and photocatalysis

Constructing the stable, low-cost, efficient, and highly adaptable visible light-driven photocatalyst to implement the synergistic effect of photocatalysis and adsorption has been excavated a promising strategy to deal with antibiotic pollution in water bodies. Herein, a novel 3D ternary Z-scheme heterojunction photocatalyst Ni₂P/Bi₂MoO₆/g-C₃N₄ (Ni₂P/BMO/CN) was fabricated by a simple solvothermal method in which the broad spectrum antibiotics (mainly tetracyclines and supplemented by quinolones) were used as target pollution sources to evaluate its adsorption and photocatalytic performance. Notably, the Z-scheme composite significantly exhibit the enhancement for degradation efficiency of tetracycline and other antibiotic by using Ni₂P nanoparticles as electron conductor. Active species capture experiment and electron spin resonance (ESR) technology reveal the mechanism of Z-scheme Ni₂P/BMO/CN photocatalytic reaction in detail. In addition, based on the identification of intermediates by liquid chromatography–mass spectroscopy (LC–MS), the possible photocatalytic degradation pathways of TC were proposed.     

Characteristics of Al-MCM-41 supported Pt catalysts: effect of Al distribution in Al-MCM-41 on its catalytic activity in naphthalene hydrogenation

Naphthalene hydrogenation was carried out in a high-pressure batch reactor over platinum catalysts supported on Al-MCM-41 where aluminum was incorporated through two different methods: a direct sol–gel method (Pre) and post-synthetic grafting method (Post). The catalytic reaction was also performed in the presence of dibenzothiophene to investigate the sulfur tolerance. The hydrogenation activity, selectivity and the sulfur tolerance strongly depended on the acidic nature of Al-MCM-41 support. It was suggested that the acid sites of Al-MCM-41-Post be more accessible than those of Al-MCM-Pre due to different aluminum distribution within the pore wall. The naphthalene and tetralin conversion increased with the acid amount of the supports in Pt/Al-MCM-41 catalysts. The acid sites in bifunctional catalysts seemed to contribute to alternative pathway by the spillover hydrogen in the acid–metal interfacial region for naphthalene hydrogenation, since the metal dispersions were kept constant for Pt/Al-MCM-41 catalysts. The trans-decalin selectivity generally increased with temperature or acid amount. The acid sites seemed to enhance the sulfur tolerance of supported platinum catalysts due to the electron-deficient state of metal.     

Ni2P/SBA-15耦合[Bmim]BF4催化加氢脱氮的新过程

通过改性固体催化剂,耦合离子液体进行催化反应,实现了在温和条件下催化加氢脱氮性能的提高。采用助剂Mo对Ni₂P/SBA-15催化剂进行改性,并用XRD、BET、XPS对催化剂结构进行表征。以吡啶为含氮模型化合物,将固体催化剂耦合[Bmim]BF₄在温和的条件下进行加氢脱氮活性评价。结果表明,低温时的脱氮过程主要以离子液体萃取为主;随着温度的升高,耦合加氢脱氮效果表现显著,且改性后的5% Mo-25% Ni₂P/SBA-15催化剂耦合离子液体在150℃、3 MPa的条件下评价脱氮率最高,达到了80.1%。离子液体4次加氢循环之后,其加氢性能没有明显的下降。离子液体的参与使得催化加氢脱氮反应在温和的条件下得以实现,这为催化加氢在低温低压条件下提供了新的理论和工艺。