探究Cu/ZnO相互作用对CO2加氢制甲醇反应性能的影响

Using renewable green hydrogen and carbon dioxide (CO₂) to produce methanol is one of the fundamental ways to reduce CO₂ emissions in the future, and research and development related to catalysts for efficient and stable methanol synthesis is one of the key factors in determining the entire synthesis process. Metal nanoparticles stabilized on a support are frequently employed to catalyze the methanol synthesis reaction. Metal-support interactions (MSIs) in these supported catalysts can play a significant role in catalysis. Tuning the MSI is an effective strategy to modulate the activity, selectivity, and stability of heterogeneous catalysts. Numerous studies have been conducted on this topic; however, a systematic understanding of the role of various strengths of MSI is lacking. Herein, three Cu/ZnO-SiO₂ catalysts with different strengths of MSI, namely, normal precipitation Cu/ZnO-SiO₂ (Nor-CZS), co-precipitation Cu/ZnO-SiO₂ (Co-CZS), and reverse precipitation Cu/ZnO-SiO₂ (Re-CZS), were successfully prepared to determine the role of such interactions in the hydrogenation of CO₂ to methanol. The results of temperature-programmed reduction (H₂-TPR) and X-ray photoelectron spectroscopy (XPS) characterization illustrated that the MSI of the catalysts was considerably affected by the precipitation sequence. Fourier transform infrared reflection spectroscopy (FT-IR) results indicated that the Cu species existed as CuO in all cases and that copper phyllosilicate was absent (except for strong Cu-SiO₂ interaction). Transmission electron microscopy (TEM), X-ray diffraction (XRD), and N₂O chemical titration results revealed that strong interactions between the Cu and Zn species would promote the dispersion of Cu species, thereby leading to a higher CO₂ conversion rate and improved catalytic stability. As expected, the Re-CZS catalyst exhibited the highest activity with 12.4% CO₂ conversion, followed by the Co-CZS catalyst (12.1%), and the Nor-CZS catalyst (9.8%). After the same reaction time, the normalized CO₂ conversion of the three catalysts decreased in the following order: Re-CZS (75%) > Co-CZS (70%) > Nor-CZS (65%). Notably, the methanol selectivity of the Re-CZS catalyst was found to level off after a prolonged period, in contrast to that of Co-CZS and Nor-CZS. Investigation of the structural evolution of the catalyst with time on stream revealed that the high methanol selectivity of the catalyst was caused by the reconstruction of the catalyst, which was induced by the strong MSI between the Cu and Zn species, and the migration of ZnO onto Cu species, which caused an enlargement of the Cu/ZnO interface. This work offers an alternative strategy for the rational and optimized design of efficient catalysts.     

Ti2(OMe)4/SiO2催化剂的制备及其合成碳酸二甲酯的反应性能

采用表面改性和离子交换法制备了SiO2负载的Ti2(OMe)4双核桥联配合物催化剂，用IR、TPD和微反技术考察了催化剂的表面构造及CO2和CH3OH在催化剂表面上的化学吸附和反应性能。结果表明：双核桥联配合物Ti2(OMe)4以Ti-O-Si键锚定在SiO2表面上；CO2在催化剂表面存在桥式和甲氧碳酸酯基两种吸附态，其中甲氧碳酸酯基吸附态是生成DMC的关键物种；CH3OH在催化剂上只有一种分子吸附态。在150℃以下，CO2和CH3OH在Ti2(OMe)4/SiO2催化剂表面上高选择地生成碳酸二甲酯。     

邻苯二胺合钴氧合反应的研究Ⅰ 水溶液中配合物及其氧合配合物稳定常数的测定

自１９３８年Tsumaki报道犤１犦氧载体以来，这方面的研究已有很大进展犤２犦，只是理论研究居多。氧载体的氧合常数是氧载体研究中的一个重要参数，它的测定是氧载体研究中的一项重要内容，用pH电位法测定氧载体的氧合常数已有研究报道犤２～４犦，作者在研究中发现，邻苯二胺合钴（o－Phdn－Co）配合物在固相和水溶液中与O２反应时表现出很大差异，其反应产物的组成比分别为液相配合物Co∶O２＝２∶１，而固相配合物Co∶O２＝１∶２，为究其成因和进行理论探讨，有必要先测定其氧合常数。由于o－Phdn－Co配合物的配位常数也未见文献…     

MoCo/Y, MoNi/Y氮化物催化剂的结构和CH4+CO2重整反应性能

采用氨气还原法制备了NaY分子筛负载的MoCo/Y、MoNi／Y双组氮化物催化剂，用XRD和EXAFS方法征了样品的结构，并测定了其在CH4＋CO2重整反应中的活性，在氧化态时，MoCo/Y样品中主要存在CoMoO4和Co3O4两种物相，Mo的配位状态接近于CoMoO4，而Co的配位状态更接近于Co3O4，MoNi／Y样品中主要有NiMoO4和NiO两种物相，Mo的配位状态接近于MiMoO4，而Ni的配位状态可能是NiMoO4和NiO两种化合物中Ni配位状态的平均效果，Ni-Mo之间的朴素作用似乎比Co-Mo相对较强，在氮化态时，两种样品中Mo的配位状态较为相似，但即不同于MoO3，也不同于单组分γ－Mo2N.Co和Ni的配位状态都不同于各在氧化态下的状态，且都在相同的位置出现一个新强峰，这似乎表明MoCo和MoNi生成了结构相似的氮化物，在CH4＋CO2重整反应中，氮化态MoCO/Y和MoNi/Y的活性大大超过非负载单组分γ－Mo2N催化剂，其中MoNi/Y的活性相对更好一些，且活性随Ni含量增加而提高。     

硫化态K—Mo合成低碳醇催化剂的制备条件和载体效应研究

用浸渍法制备以KCl为助剂的ZrO_2、γ-Al_2O_3和SiO_2负载硫化态钼基催化剂,研究了钼和助剂钾两种组分浸渍顺序、助剂含量、载体差别以及浸渍溶液的酸碱性对催化剂上CO加氢合成低碳混合醇性能的影响。ZrO_2按先钼后钾、γ-Al_2O_3和SiO_2则按相反的顺序浸渍两种组分、且K/Mo原子比分别为0.5,0.8和1.0制备催化剂,其合成醇活性最佳。由于载体性质的差异,K-Mo/SiO_2、特别是K-Mo/ZrO_2的合成醇活性强烈依赖于钾助剂含量。而K-Mo/SiO_2在较宽的钾含量范围内,其活性差别不明显。适当选择较高碱性的浸渍溶液制备K-Mo/γ-Al_2O_3催化剂,有利于醇活性的提高。     

液化石油气水蒸气重整镍催化剂新型载体研究

以共沉淀法合成了硅铝系载体（AS和SA），并采用改性天然高铝石为原料合成了矿物质载体（MC-1和MC-2）,采用浸渍法合成了镍负载型催化剂。用常压固定床管式反应器，考察了液化石油气水蒸气重整反应活性，通过XRD、物理吸附等手段对催化剂进行了表征。结果表明，以MC-1、MC-2和SA、AS为载体的催化剂的水蒸气重整活性明显高于目前普遍使用的Ni/α-Al2O3催化剂。以SA为载体，负载5%镍的催化剂具有最好的水蒸气重整活性。在750 ℃，水碳比为2.0的条件下转化率达100％，C1选择性达94.46％。XRD分析结果表明1 300 ℃焙烧后的SA载体中存在α-Al2O3晶型和莫来石结构。硅、铝添加次序对水蒸气重整活性影响较大，硅-铝添加次序的催化剂样品的活性高于铝-硅添加次序的样品，C1选择性提高12.7％。     

MoO3、NiO、ZnO在小表面金红石上的分散行为

Dispersion of MoO3, NiO, ZnO on rutile TiO2 with low specific surface area was studied with Mercury Porosimeter, SEM, XPS and Ammonia Extraction method. The dispersion thresholds of MoO3, NiO, ZnO on three rutile TiO2 carriers were obtained with XPS, and com-pared with those on anatase TiO2 with high specific surf are area. Ammonia Extraction method was used to identify the surface oxide species interarting with support surface in different strength and it was found that the proportions of oxides that can not be extracted by ammonia extraction are different for MoO3, NiO and ZnO which are supported on rutile TiO2.     

稀土氧化物对甲烷蒸汽转化反应NiO／α—Al2O3催化剂的影响

用微型反应器和XRD等技术研究了稀土氧化物(RE_xO_y)对甲烷水蒸汽转化反应NiO/α-Al_2O_3催化剂性能的影响。结果表明,制备方法(如浸渍顺序)和稀土氧化物的种类均影响催化剂组份镍的分散度。稀土氧化物是通过抑制镍的晶粒长大、金属镍的氧化以及NiO-Al_2O_3间的相互作用,改善了催化剂的活性、稳定性和抗高温水蒸汽作用的能力。稀土氧化物对镍系催化剂的稳定效应与金属和添加剂间的相互作用有关。     

球笼烯（C_（60）／C_（70）载体钕系催化丁二烯聚合的研究

球笼烯（Ｃ_（６０）／Ｃ_（７０）载体钕系催化丁二烯聚合的研究赵春英，陈滇宝，仲崇祺，董文寰，徐玲，唐学明（青岛化工学院高分子材料系青岛２６６０４２）杨海滨，李明辉，邹广田（吉林大学超硬材料国家重点实验室长春１３００２３）关键词球碳载体钕系催化剂，聚丁...     

碳点增强的Ru纳米颗粒复合材料用于碱性条件下高效电解水析氢

In the 21st century, hydrogen energy is a novel energy source. Its use is expected to mitigate the problems of environmental pollution and global warming caused by the excessive use of conventional fossil fuels. The hydrogen evolution reaction (HER) for water splitting has attracted considerable attention because of its environmental friendliness. To improve electrocatalyst performance and reduce operation cost, carbon-based metal hybrid materials exhibiting high efficiency and catalytic activity have been developed. Among them, carbon dots (CDs) have garnered significant research attention and have been widely applied in biosensing, bioimaging, and energy conversion/storage because of their facile synthesis, biocompatibility, tunable photoluminescence, excellent stability, and good electronic properties. CDs are widely used as carriers in the construction of electrocatalysts prepared from carbon-based metal hybrid materials. At present, it is believed that CDs exhibit excellent confinement effects, which can effectively inhibit the growth and agglomeration of metal nanoparticles, thereby preparing well-distributed carbon-based metal hybrid materials with a uniform and controllable size. However, the formation process of the small-molecule raw materials of CDs has not been elucidated. In this study, CDs and small-molecule raw materials from synthetic CDs were used as precursors to prepare nitrogen-doped CD-supported ruthenium nanoparticle (Ru@CDs) and small-molecule-supported ruthenium nanoparticle (Ru@Molecule) hybrid materials, respectively. The interaction between the small molecules and Ru in the process of CD formation and the effect on HER performance were explored. Moreover, we prepared different carriers such as metal organic frameworks(MOF), carbon nanotubes (CNTs), and graphene (GO)-supported ruthenium nanoparticle hybrid materials. Among them, Ru@CDs exhibited controllable size and excellent dispersibility and exhibited outstanding HER activity and good stability. Ru@CDs were found to require a low overpotential of 22 mV to reach a current density of 10 mA·cm⁻². Moreover, we observed the presence of an intermediate state between the molecules and CDs and demonstrated that the intermediate state exhibits no confinement effect. Furthermore, we found that with increasing calcination temperature, the intermediate state gradually changes to CDs. The unique spatial confinement between CDs and metal ions is key to the formation of monodisperse Ru nanoparticles. Our results confirmed that Ru@CDs serve as excellent HER catalyst supports. This work not only reveals the effect of the unique spatial confinement of CDs on the supported metals and their promoting effect on electrocatalytic activity but also provides guides the future development of CD-based metal hybrid electrocatalysts.