Catalytic Consequences of Oxidant, Alkene, and Pore Structures on Alkene Epoxidations within Titanium Silicates
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Rebecca L. Schultz | D. Bregante | E. Z. Ayla | J. Tan | David S. Potts | D. Flaherty | Chris Torres
[1] D. Bregante,et al. Heteroatom substituted zeolite FAU with ultralow Al contents for liquid-phase oxidation catalysis , 2020 .
[2] D. Bregante,et al. Impact of Specific Interactions Among Reactive Surface Intermediates and Confined Water on Epoxidation Catalysis and Adsorption in Lewis Acid Zeolites , 2019, ACS Catalysis.
[3] R. Errington,et al. Why Does Nb(V) Show Higher Heterolytic Pathway Selectivity Than Ti(IV) in Epoxidation with H2O2? Answers from Model Studies on Nb- and Ti-Substituted Lindqvist Tungstates , 2019, ACS Catalysis.
[4] J. Greeley,et al. Cooperative Effects between Hydrophilic Pores and Solvents: Catalytic Consequences of Hydrogen Bonding on Alkene Epoxidation in Zeolites. , 2019, Journal of the American Chemical Society.
[5] D. Bregante,et al. Direct synthesis of H2O2 on PdZn nanoparticles: The impact of electronic modifications and heterogeneity of active sites , 2018, Journal of Catalysis.
[6] S. Zones,et al. Isomerization and β-scission reactions of alkanes on bifunctional metal-acid catalysts: Consequences of confinement and diffusional constraints on reactivity and selectivity , 2018, Journal of Catalysis.
[7] Evan C. Wegener,et al. Dominant Role of Entropy in Stabilizing Sugar Isomerization Transition States within Hydrophobic Zeolite Pores. , 2018, Journal of the American Chemical Society.
[8] Rajamani Gounder,et al. Influence of confining environment polarity on ethanol dehydration catalysis by Lewis acid zeolites , 2018, Journal of Catalysis.
[9] F. Ribeiro,et al. Propylene oxide inhibits propylene epoxidation over Au/TS-1 , 2018, Journal of Catalysis.
[10] David W. Flaherty,et al. Catalytic thiophene oxidation by groups 4 and 5 framework-substituted zeolites with hydrogen peroxide: Mechanistic and spectroscopic evidence for the effects of metal Lewis acidity and solvent Lewis basicity , 2018, Journal of Catalysis.
[11] S. Zones,et al. Outer-Sphere Control of Catalysis on Surfaces: A Comparative Study of Ti(IV) Single-Sites Grafted on Amorphous versus Crystalline Silicates for Alkene Epoxidation. , 2018, Journal of the American Chemical Society.
[12] R. Crabtree,et al. Key factors in pincer ligand design. , 2018, Chemical Society reviews.
[13] Justin M. Notestein,et al. Consequences of Confinement for Alkene Epoxidation with Hydrogen Peroxide on Highly Dispersed Group 4 and 5 Metal Oxide Catalysts , 2018 .
[14] Lise‐Marie Chamoreau,et al. Unveiling the Active Surface Sites in Heterogeneous Titanium-Based Silicalite Epoxidation Catalysts: Input of Silanol-Functionalized Polyoxotungstates as Soluble Analogues , 2018 .
[15] Justin M. Notestein,et al. Rate and Selectivity Control in Thioether and Alkene Oxidation with H2O2 over Phosphonate‐Modified Niobium(V)–Silica Catalysts , 2017 .
[16] D. Bregante,et al. Periodic Trends in Olefin Epoxidation over Group IV and V Framework-Substituted Zeolite Catalysts: A Kinetic and Spectroscopic Study. , 2017, Journal of the American Chemical Society.
[17] Michele L. Sarazen,et al. Stability of bound species during alkene reactions on solid acids , 2017, Proceedings of the National Academy of Sciences.
[18] D. Bregante,et al. Kinetic and spectroscopic evidence for reaction pathways and intermediates for olefin epoxidation on Nb in *BEA , 2017 .
[19] D. Bregante,et al. Production and use of H2O2 for atom-efficient functionalization of hydrocarbons and small molecules , 2017 .
[20] Susannah L. Scott,et al. Phenomena Affecting Catalytic Reactions at Solid–Liquid Interfaces , 2016 .
[21] A. B. Thompson,et al. Synthesis−Structure–Function Relationships of Silica-Supported Niobium(V) Catalysts for Alkene Epoxidation with H2O2 , 2016 .
[22] Pierangelo Metrangolo,et al. The Halogen Bond , 2016, Chemical reviews.
[23] V. Kaichev,et al. Mesoporous niobium-silicates prepared by evaporation-induced self-assembly as catalysts for selective oxidations with aqueous H2O2 , 2015 .
[24] A. B. Thompson,et al. Periodic Trends in Highly Dispersed Groups IV and V Supported Metal Oxide Catalysts for Alkene Epoxidation with H2O2 , 2015 .
[25] M. Clerici. The activity of titanium silicalite-1 (TS-1): Some considerations on its origin , 2015, Kinetics and Catalysis.
[26] R. Snurr,et al. A kinetic study of vapor-phase cyclohexene epoxidation by H2O2 over mesoporous TS-1 , 2015 .
[27] A. B. Thompson,et al. Counting Active Sites on Titanium Oxide–Silica Catalysts for Hydrogen Peroxide Activation through In Situ Poisoning with Phenylphosphonic Acid , 2014 .
[28] Rajamani Gounder. Hydrophobic microporous and mesoporous oxides as Brønsted and Lewis acid catalysts for biomass conversion in liquid water , 2014 .
[29] O. A. Kholdeeva,et al. Recent developments in liquid-phase selective oxidation using environmentally benign oxidants and mesoporous metal silicates , 2014 .
[30] R. Zanoni,et al. Molybdenum-MCM-41 silica as heterogeneous catalyst for olefin epoxidation , 2014 .
[31] A. Corma,et al. Advances in the synthesis of titanosilicates: From the medium pore TS-1 zeolite to highly-accessible ordered materials , 2014 .
[32] E. Iglesia,et al. Transition-state enthalpy and entropy effects on reactivity and selectivity in hydrogenolysis of n-alkanes. , 2013, Journal of the American Chemical Society.
[33] Mark E. Davis,et al. Beyond shape selective catalysis with zeolites: Hydrophobic void spaces in zeolites enable catalysis in liquid water , 2013 .
[34] M. Clerici,et al. Oxidation Reactions Catalyzed by Transition‐Metal‐Substituted Zeolites , 2013 .
[35] Carlo Lamberti,et al. Reactivity of surface species in heterogeneous catalysts probed by in situ X-ray absorption techniques. , 2013, Chemical reviews.
[36] M. Serio,et al. Chemical and Technical Aspects of Propene Oxide Production via Hydrogen Peroxide (HPPO Process) , 2013 .
[37] R. Crabtree,et al. Outer sphere hydrogenation catalysis , 2013 .
[38] I. D. Ivanchikova,et al. Alkene oxidation by Ti-containing polyoxometalates. Unambiguous characterization of the role of the protonation state. , 2012, Chemical communications.
[39] Chang Won Yoon,et al. Mechanism of the Decomposition of Aqueous Hydrogen Peroxide over Heterogeneous TiSBA15 and TS-1 Selective Oxidation Catalysts: Insights from Spectroscopic and Density Functional Theory Studies , 2011 .
[40] R. Sanz,et al. Hierarchical TS-1 zeolite synthesized from SiO2 TiO2 xerogels imprinted with silanized protozeolitic units , 2011 .
[41] Justin M. Notestein,et al. Grafted Ta-calixarenes: tunable, selective catalysts for direct olefin epoxidation with aqueous hydrogen peroxide. , 2010 .
[42] S. Kaliaguine,et al. Controlled Postgrafting of Titanium Chelates for Improved Synthesis of Ti-SBA-15 Epoxidation Catalysts , 2010 .
[43] Jernej Stare,et al. Mechanistic Aspects of Propene Epoxidation by Hydrogen Peroxide. Catalytic Role of Water Molecules, External Electric Field, and Zeolite Framework of TS-1 , 2009, J. Chem. Inf. Model..
[44] Daniel A. Ruddy,et al. Kinetics and mechanism of olefin epoxidation with aqueous H2O2 and a highly selective surface-modified TaSBA15 heterogeneous catalyst. , 2008, Journal of the American Chemical Society.
[45] R. Brutchey,et al. The Influence of Surface Modification on the Epoxidation Selectivity and Mechanism of TiSBA15 and TaSBA15 Catalysts with Aqueous Hydrogen Peroxide , 2008 .
[46] A. Bhan,et al. Entropy considerations in monomolecular cracking of alkanes on acidic zeolites , 2008 .
[47] L. K. Andersen,et al. Influence of surface modification of Ti-SBA15 catalysts on the epoxidation mechanism for cyclohexene with aqueous hydrogen peroxide. , 2005, Langmuir : the ACS journal of surfaces and colloids.
[48] Eric V. Anslyn,et al. Modern Physical Organic Chemistry , 2005 .
[49] P. Ratnasamy,et al. Active Sites and Reactive Intermediates in Titanium Silicate Molecular Sieves , 2004 .
[50] M. Pillinger,et al. Incorporation of a (Cyclopentadienyl)molybdenum Oxo Complex in MCM-41 and Its Use as a Catalyst for Olefin Epoxidation , 2004 .
[51] C. Lamberti,et al. Ti-Peroxo Species in the TS-1/H2O2/H2O System , 2004 .
[52] C. Lamberti,et al. The structure of the peroxo species in the TS-1 catalyst as investigated by resonant Raman spectroscopy. , 2002, Angewandte Chemie.
[53] C. Catlow,et al. On the structure and coordination of the oxygen-donating species in Ti↑MCM-41/TBHP oxidation catalysts: a density functional theory and EXAFS study , 2002 .
[54] T. Tatsumi,et al. Epoxidation of cyclic alkenes with hydrogen peroxide and tert-butyl hydroperoxide on Na-containing Tiβ zeolites , 2001 .
[55] C. Catlow,et al. The Three-Dimensional Structure of the Titanium-Centered Active Site during Steady-State Catalytic Epoxidation of Alkenes , 2001 .
[56] J. Mayoral,et al. Is MCM-41 really advantageous over amorphous silica? The case of grafted titanium epoxidation catalysts , 2001 .
[57] C. Catlow,et al. The architecture of catalytically active centers in titanosilicate (TS-1) and related selective-oxidation catalysts , 2000 .
[58] E. Derouane. Zeolites as solid solvents , 1998 .
[59] P. Jacobs,et al. Chromatographic Study of Adsorption of n-Alkanes on Zeolites at High Temperatures , 1998 .
[60] A. Corma,et al. Direct Synthesis and Characterization of Hydrophobic Aluminum-Free Ti−Beta Zeolite , 1998 .
[61] Mark E. Davis,et al. Characterization and catalytic activity of titanium containing SSZ-33 and aluminum-free zeolite beta , 1996 .
[62] A. Corma,et al. Solvent Effects during the Oxidation of Olefins and Alcohols with Hydrogen Peroxide on Ti-Beta Catalyst: The Influence of the Hydrophilicity–Hydrophobicity of the Zeolite , 1996 .
[63] David White,et al. Quantification of Steric Effects in Organometallic Chemistry. , 1994 .
[64] Mark E. Davis,et al. Studies on the Catalytic-Oxidation of Alkanes and Alkenes by Titanium Silicates , 1994 .
[65] A. Corma,et al. Activity of Ti-Beta Catalyst for the Selective Oxidation of Alkenes and Alkanes , 1994 .
[66] M. Clerici,et al. Epoxidation of Lower Olefins with Hydrogen Peroxide and Titanium Silicalite , 1993 .
[67] H. Mimoun. Do metal peroxides as homolytic and heterolytic oxidative reagents. Mechanism of the halcon epoxidation process , 1987 .
[68] L. Saussine,et al. Selective epoxidation of olefins by oxo[N-(2-oxidophenyl)salicylidenaminato]vanadium(V) alkylperoxides. On the mechanism of the Halcon epoxidation process , 1986 .
[69] M. Boudart,et al. Experimental criterion for the absence of artifacts in the measurement of rates of heterogeneous catalytic reactions , 1982 .
[70] J. K.,et al. Industrial Organic Chemistry , 1938, Nature.
[71] S. P. Sadtler. Industrial organic chemistry , 1912 .