个人信息Personal Information
教授
博士生导师
硕士生导师
任职 : 大连理工大学成都研究院院长
性别:男
毕业院校:中科院大连化学物理研究所
学位:博士
所在单位:化工学院
学科:化学工艺. 物理化学. 功能材料化学与化工
办公地点:大连理工大学西部校区化工综合楼A401室
联系方式:辽宁省大连市高新区凌工路2号,邮编116024
电子邮箱:changhai@dlut.edu.cn
Synthesis and catalytic properties of nickel silicide catalysts for selective hydrogenation
点击次数:
论文类型:会议论文
发表时间:2021-01-26
摘要:Hydrotreating research has played an important role in environmental catalysis studies worldwide. This has led to a strong interest in catalytic materials di?erent from the classically utilized metal sul?de and noble metal catalysts. Metal carbides and nitrides are initially highly active, but are easily poisoned by a small amount of sulfur. Thermochemical calculations have indicated that metal silicides can tolerate much higher H 2S concentrations than the corresponding carbides and nitrides. Therefore, we explored the possibility of using metal silicides as novel catalysts for heterogeneous catalytic reactions. Nickel-silicon intermetallic catalysts (Ni 2Si, NiSi, and NiSi 2) were prepared by direct silification method using SiH 2 as the silicon source. The as prepared nickel silicides were characterized by X-ray diffraction, transmission electron microscopy, magnetic measurements, X-ray photoelectron spectroscopy, temperature-programmed reduction, temperature-programmed desorption measurements. The results show that nickel silicide formation involves the following sequence as a function of increasing temperature: Ni (cubic) Ni 2Si (orthorhombic) NiSi (orthorhombic) NiSi 2 (cubic). The insertion of Si atoms into the interstitial sites between Ni atoms resulted in a significant change in the unit cell lattice of nickel. All of nickel silicide materials were ferromagnetic at room temperature, with saturation magnetization values drastically decreased when Si is present. Nickel silicide develops a thin silicon oxide layer during exposure to air, which can be removed by H 2-temperature programmed reduction. The catalytic hydrogenation of cinnamaldehyde and phenylacetylene over the nickel silicide nanoparticles was investigated. The repulsive force between the electronegative silicon atoms in the nickel silicide intermetallic and oxygen atoms in the C=O bond of cinnamaldehyde inhibit the hydrogenation of C=O bond to some extent. Nickel silicide catalyst presents 77% selectivity to hydrocinnamaldehyde, which is much higher than monometallic nickel catalyst. The nickel silicide catalyst also shows excellent (ca 93%) styrene selectivity in the hydrogenation of phenylacetylene due to the strong modification of electronic structure around the Fermi level caused by the interaction of nickel and silicon. These results indicate that these novel nickel silicides are promising catalysts for the selective hydrogenation of unsaturated hydrocarbons.