Enhancing the Catalytic Activity of Zn-Containing Magnetic Oxides in a Methanol Synthesis: Identifying the Key Factors.
暂无分享,去创建一个
D. Morgan | A. Sidorov | M. Sulman | L. Bronstein | Z. Shifrina | N. Kuchkina | J. Dittmar | Barry D. Stein | M. Pink | Y. Losovyj | O. L. Lependina | E. Serkova | N. Baird | M. Grigoriev
[1] Le Wang,et al. Enhanced photoluminescence of Fe3O4@Y2O3:Eu3+ bifunctional nanoparticles by the Gd3+ co-doping , 2016 .
[2] Tianhao Wang,et al. Zinc-Containing Magnetic Oxides Stabilized by a Polymer: One Phase or Two? , 2016, ACS Applied Materials and Interfaces.
[3] P. Vlasov,et al. Hyperbranched pyridylphenylene polymers based on the first-generation dendrimer as a multifunctional monomer , 2015 .
[4] Blas P. Uberuaga,et al. Non-uniform Solute Segregation at Semi-Coherent Metal/Oxide Interfaces , 2015, Scientific Reports.
[5] R. Rioux,et al. In Situ Spectroscopic Characterization of Ni1–xZnx/ZnO Catalysts and Their Selectivity for Acetylene Semihydrogenation in Excess Ethylene , 2015 .
[6] R. Schlögl,et al. Promoting Strong Metal Support Interaction: Doping ZnO for Enhanced Activity of Cu/ZnO:M (M = Al, Ga, Mg) Catalysts , 2015 .
[7] S. K. Mishra,et al. Enhancement of photoluminescence emission and anomalous photoconductivity properties of Fe3O4@SiO2 core–shell microspheres , 2015 .
[8] Wenyi Huang,et al. The synthesis of ultrasmall ZnO@PEG nanoparticles and its fluorescence properties , 2015, Journal of Sol-Gel Science and Technology.
[9] X. Zhang,et al. Hierarchical nanostructures of nickel-doped zinc oxide: Morphology controlled synthesis and enhanced visible-light photocatalytic activity , 2015 .
[10] D. Marx,et al. Methanol synthesis on ZnO(0001¯). IV. Reaction mechanisms and electronic structure. , 2014, The Journal of chemical physics.
[11] Hong Xu,et al. Photoluminescence and photothermal effect of Fe3O4 nanoparticles for medical imaging and therapy , 2014 .
[12] D. Astruc,et al. Fast-growing field of magnetically recyclable nanocatalysts. , 2014, Chemical reviews.
[13] Chi-Jung Chang,et al. Synthesis and characterization of Cr-doped ZnO nanorod-array photocatalysts with improved activity , 2014 .
[14] A. Beale,et al. Chemical imaging of the sulfur-induced deactivation of Cu/ZnO catalyst bodies , 2014 .
[15] Klaus‐Joachim Jens,et al. Low-Temperature and Low-Pressure Methanol Synthesis in the Liquid Phase Catalyzed by Copper Alkoxide Systems , 2014 .
[16] A. Bazgir,et al. Copper ferrite nanoparticles: an efficient and reusable nanocatalyst for a green one-pot, three-component synthesis of spirooxindoles in water. , 2013, ACS combinatorial science.
[17] Jianping Xu,et al. Luminescence Properties of Cobalt-Doped ZnO Films Prepared by Sol–Gel Method , 2013, Journal of Electronic Materials.
[18] T. Chatterjee,et al. Magnetically Separable CuFe2O4 Nanoparticles Catalyzed Ligand-Free CS Coupling in Water: Access to (E)- and (Z)-Styrenyl-, Heteroaryl and Sterically Hindered Aryl Sulfides , 2013 .
[19] T. Shanmugapriya,et al. Photoluminescence Enhancement of Nanogold Decorated CdS Quantum Dots , 2013 .
[20] C. Sujatha,et al. Optimization of UV emission intensity of ZnO nanoparticles by changing the excitation wavelength , 2013 .
[21] J. Salem,et al. Synthesis, structural and optical properties of Ni-doped ZnO micro-spheres , 2013, Journal of Materials Science: Materials in Electronics.
[22] R. Schlögl,et al. Performance improvement of nanocatalysts by promoter-induced defects in the support material: methanol synthesis over Cu/ZnO:Al. , 2013, Journal of the American Chemical Society.
[23] M. Langell,et al. Comparison of Nanoscaled and Bulk NiO Structural and Environmental Characteristics by XRD, XAFS, and XPS , 2012 .
[24] R. Varma,et al. A simple and facile Heck-type arylation of alkenes with diaryliodonium salts using magnetically recoverable Pd-catalyst , 2012 .
[25] X. Huang,et al. Influence of Fe and Co and Cr Doped Amount on the Photoactivating Property of Nanometer ZnO Powder , 2012 .
[26] M. Muhler,et al. Preparation, microstructure characterization and catalytic performance of Cu/ZnO and ZnO/Cu composite nanoparticles for liquid phase methanol synthesis. , 2012, Physical chemistry chemical physics : PCCP.
[27] B. Paul,et al. Synthesis of nickel nanoparticles by hydrazine reduction: mechanistic study and continuous flow synthesis , 2012, Journal of Nanoparticle Research.
[28] Rafael Luque,et al. Magnetically recoverable nanocatalysts. , 2011, Chemical reviews.
[29] Yang Tian,et al. Facile solvothermal synthesis of monodisperse Fe3O4 nanocrystals with precise size control of one nanometre as potential MRI contrast agents , 2011 .
[30] A. Diaz,et al. Investigation of the Effect of Gd3+ on Host-to-Europium Transfer Efficiency in (Y,Gd)BO3:Eu3+ Under VUV Excitation , 2010 .
[31] Dongen Zhang,et al. High quality self-assembly magnetite (Fe(3)O(4)) chain-like core-shell nanowires with luminescence synthesized by a facile one-pot hydrothermal process. , 2010, Chemical Communications.
[32] A. Yamada,et al. Breakdown of the Hume-Rothery rules in sub-nanometer-sized Ta-containing bimetallic small clusters. , 2009, The journal of physical chemistry. A.
[33] M. Muhler,et al. The surface chemistry of ZnO nanoparticles applied as heterogeneous catalysts in methanol synthesis , 2009 .
[34] Ruiqin Yang,et al. A new method of low-temperature methanol synthesis on Cu/ZnO/Al2O3 catalysts from CO/CO2/H2 , 2008 .
[35] T. Yamashita,et al. Analysis of XPS spectra of Fe2+ and Fe3+ ions in oxide materials , 2008 .
[36] Monalisa,et al. Supported Ultra Small Palladium on Magnetic Nanoparticles Used as Catalysts for Suzuki Cross-Coupling and Heck Reactions , 2007 .
[37] Lixia Yuan,et al. Characteristics of bio-oil-syngas and its utilization in fischer-tropsch synthesis , 2007 .
[38] L. Rossi,et al. Superparamagnetic nanoparticle-supported palladium: a highly stable magnetically recoverable and reusable catalyst for hydrogenation reactions , 2007 .
[39] A. Lu,et al. Magnetic nanoparticles: synthesis, protection, functionalization, and application. , 2007, Angewandte Chemie.
[40] M. Muhler,et al. On the role of oxygen defects in the catalytic performance of zinc oxide. , 2006, Angewandte Chemie.
[41] B. Meyer,et al. Active sites on oxide surfaces: ZnO-catalyzed synthesis of methanol from CO and H2. , 2005, Angewandte Chemie.
[42] Martyn V. Twigg,et al. Deactivation of Copper Metal Catalysts for Methanol Decomposition, Methanol Steam Reforming and Methanol Synthesis , 2003 .
[43] V. Biju,et al. Electronic Structure of Nanostructured Nickel Oxide Using Ni 2p XPS Analysis , 2002 .
[44] S. V. Narasimhan,et al. Formation of zinc ferrite by solid-state reaction and its characterization by XRD and XPS , 2001 .
[45] Junji Nakamura,et al. The role of ZnO in Cu/ZnO methanol synthesis catalysts — morphology effect or active site model? , 2001 .
[46] Junji Nakamura,et al. The chemical modification seen in the Cu/ZnO methanol synthesis catalysts , 2000 .
[47] C. Powell,et al. Evaluation of Calculated and Measured Electron Inelastic Mean Free Paths Near Solid Surfaces , 1999 .
[48] G. Sawatzky,et al. In situ XPS analysis of various iron oxide films grown by NO2-assisted molecular-beam epitaxy , 1999 .
[49] L. Tagliabue,et al. Synthesis of short chain alcohols over a Cs-promoted Cu/ZnO/Cr2O3 catalyst , 1998 .
[50] J. Sanz,et al. An XPS study of thin NiO films deposited on MgO(100) , 1996 .
[51] T. Fujitani,et al. The role of ZnO in Cu/ZnO methanol synthesis catalysts , 1996 .
[52] R. G. Bass,et al. Synthesis and characterization of extended poly(phenylquinoxalines) containing carbonyl, ether and sulphide linking groups , 1995 .
[53] Andrzej Cybulski,et al. Liquid-Phase Methanol Synthesis: Catalysts, Mechanism, Kinetics, Chemical Equilibria, Vapor-Liquid Equilibria, and Modeling—A Review , 1994 .
[54] R. Schlögl,et al. The nature of the iron oxide-based catalyst for dehydrogenation of ethylbenzene to styrene 2. Surface chemistry of the active phase , 1992 .
[55] R. Herman,et al. Methanol synthesis catalysts based on cesium/copper/zinc oxide/metal oxide (metal = aluminum, chromium, gallium): genesis from coprecipitated hydrotalcite-like precursors, solid-state chemistry, morphology, and stability , 1989 .
[56] Edward I. Solomon,et al. X-ray absorption edge and EXAFS study of the copper sites in zinc oxide methanol synthesis catalysts , 1989 .
[57] B. M. Dekoven,et al. Deconvolution as a correction for photoelectron inelastic energy losses in the core level XPS spectra of iron oxides , 1987 .
[58] R. West,et al. Developing detailed kinetic models of syngas production from bio-oil gasification using Reaction Mechanism Generator (RMG) , 2016 .
[59] Xuan Wang,et al. Optical and magnetic properties of Fe doped ZnO nanoparticles obtained by hydrothermal synthesis , 2014 .
[60] N. Koshida,et al. Energy transfer induced Eu3+ photoluminescence enhancement in tellurite glass , 2012 .
[61] R. Varma,et al. O-Allylation of phenols with allylic acetates in aqueous media using a magnetically separable catalytic system , 2012 .
[62] Z. Shifrina,et al. New fluorinated poly(phenylquinoxalines) , 2001 .
[63] R. Herman,et al. Promotion of methanol synthesis over Cu/ZnO catalysts by doping with caesium , 1986 .