Catalysis by Design: Well-Defined Single-Site Heterogeneous Catalysts.

Heterogeneous catalysis, a field important industrially and scientifically, is increasingly seeking and refining strategies to render itself more predictable. The main issue is due to the nature and the population of catalytically active sites. Their number is generally low to very low, their "acid strengths" or " redox properties" are not homogeneous, and the material may display related yet inactive sites on the same material. In many heterogeneous catalysts, the discovery of a structure-activity reationship is at best challenging. One possible solution is to generate single-site catalysts in which most, if not all, of the sites are structurally identical. Within this context and using the right tools, the catalyst structure can be designed and well-defined, to reach a molecular understanding. It is then feasible to understand the structure-activity relationship and to develop predictable heterogeneous catalysis. Single-site well-defined heterogeneous catalysts can be prepared using concepts and tools of surface organometallic chemistry (SOMC). This approach operates by reacting organometallic compounds with surfaces of highly divided oxides (or of metal nanoparticles). This strategy has a solid track record to reveal structure-activity relationship to the extent that it is becoming now quite predictable. Almost all elements of the periodical table have been grafted on surfaces of oxides (from simple oxides such as silica or alumina to more sophisticated materials regarding composition or porosity). Considering catalytic hydrocarbon transformations, heterogeneous catalysis outcome may now be predicted based on existing mechanistic proposals and the rules of molecular chemistry (organometallic, organic) associated with some concepts of surface sciences. A thorough characterization of the grafted metal centers must be carried out using tools spanning from molecular organometallic or surface chemistry. By selection of the metal, its ligand set, and the support taken as a X, L ligands in the Green formalism, the catalyst can be designed and generated by grafting the organometallic precursor containing the functional group(s) suitable to target a given transformation (surface organometallic fragments (SOMF)). The choice of these SOMF is based on the elementary steps known in molecular chemistry applied to the desired reaction. The coordination sphere necessary for any catalytic reaction involving paraffins, olefins, and alkynes also can thus be predicted. Only their most complete understanding can allow development of catalytic reactions with the highest possible selectivity, activity, and lifetime. This Account will examine the results of SOMC for hydrocarbon transformations on oxide surfaces bearing metals of group 4-6. The silica-supported catalysts are exhibiting remarkable performances for Ziegler-Natta polymerization and depolymerization, low temperature hydrogenolysis of alkanes and waxes, metathesis of alkanes and cycloalkanes, olefins metathesis, and related reactions. In the case of reactions involving molecules that do not contain carbon (water-gas shift, NH3 synthesis, etc.) this single site approach is also valid but will be considered in a later review.

[1]  E. Abou‐hamad,et al.  Well-defined single-site monohydride silica-supported zirconium from azazirconacyclopropane. , 2015, Chemistry.

[2]  J. Basset,et al.  Surface Organometallic Chemistry: A New Approach to Heterogeneous Catalysis? , 1984 .

[3]  G. C. Bailey,et al.  Olefin Disproportionation. A New Catalytic Process , 1964 .

[4]  A. Dorcier,et al.  Preparation of a Well-Defined Silica-Supported Nickel-Diimine Alkyl Complex − Application for the Gas-Phase Polymerization of Ethylene , 2009 .

[5]  S. Norsic,et al.  Production of Propylene from 1-Butene on Highly Active “Bi-Functional Single Active Site” Catalyst: Tungsten Carbene-Hydride Supported on Alumina , 2011 .

[6]  Jean-Marie Basset,et al.  Homogeneous and heterogeneous catalysis: bridging the gap through surface organometallic chemistry. , 2003, Angewandte Chemie.

[7]  S. Norsic,et al.  Non-oxidative coupling reaction of methane to ethane and hydrogen catalyzed by the silica-supported tantalum hydride: ([triple bond]SiO)2Ta-H. , 2008, Journal of the American Chemical Society.

[8]  L. Cavallo,et al.  Mechanism of n-Butane Hydrogenolysis Promoted by Ta-Hydrides Supported on Silica , 2014 .

[9]  E. Abou‐hamad,et al.  Well-defined silica-supported zirconium-imido complexes mediated heterogeneous imine metathesis. , 2016, Chemical communications.

[10]  C. Copéret,et al.  Modifying the reactivity in the homologation of propane by introducing aryloxide ligands on a silica supported zirconium alkyl system. , 2007, Dalton transactions.

[11]  I. Fragalà,et al.  Surface structural-chemical characterization of a single-site d0 heterogeneous arene hydrogenation catalyst having 100% active sites , 2012, Proceedings of the National Academy of Sciences.

[12]  J. Basset,et al.  Surface organometallic chemistry: A new approach to heterogeneous Catal.ysis ? , 1983 .

[13]  E. Abou‐hamad,et al.  Direct observation of supported W bis-methylidene from supported W-methyl/methylidyne species. , 2014, Chemical communications.

[14]  Jérémie D. A. Pelletier,et al.  Expanding the Scope of Metathesis: A Survey of Polyfunctional, Single-Site Supported Tungsten Systems for Hydrocarbon Valorization , 2014 .

[15]  Hans Schulz,et al.  Short history and present trends of Fischer–Tropsch synthesis , 1999 .

[16]  J. Paul,et al.  Development of the first well-defined tungsten oxo alkyl derivatives supported on silica by SOMC: towards a model of WO3/SiO2 olefin metathesis catalyst. , 2010, Chemical communications.

[17]  R. Psaro,et al.  Modern surface organometallic chemistry , 2009 .

[18]  J. Basset,et al.  Metathesis of Alkanes Catalyzed by Silica-Supported Transition Metal Hydrides. , 1997 .

[19]  C. Santini,et al.  Surface Organometallic Chemistry of Hf(CH2tBu)4 on Silica and Silica−Alumina: Reaction of the Resulting Grafted Hafnium Neopentyl with Dihydrogen , 2010 .

[20]  Y. Iwasawa,et al.  Spectroscopic evidence for a surface Nb carbene in a new SiO2-attached Nb catalyst active for propene metathesis , 1989 .

[21]  Glenn J. Sunley,et al.  Homologation of propane catalyzed by oxide-supported zirconium dihydride and dialkyl complexes. , 2007, Angewandte Chemie.

[22]  H. Komber,et al.  Methyltrioxorhenium as Catalyst for Olefin Metathesis , 1991 .

[23]  P. Sautet,et al.  Characterization of Surface Hydride Hafnium Complexes on Alumina by a Combination of Experiments and DFT Calculations , 2011 .

[24]  A. Hoveyda,et al.  The remarkable metal-catalysed olefin metathesis reaction , 2007, Nature.

[25]  C. Copéret,et al.  Low-Temperature Hydrogenolysis of Alkanes Catalyzed by a Silica-Supported Tantalum Hydride Complex, and Evidence for a Mechanistic Switch from Group IV to Group V Metal Surface Hydride Complexes , 2000 .

[26]  E. Abou‐hamad,et al.  Alkane metathesis with the tantalum methylidene [(≡SiO)Ta(═CH2)Me2]/[(≡SiO)2Ta(═CH2)Me] generated from well-defined surface organometallic complex [(≡SiO)Ta(V)Me4]. , 2015, Journal of the American Chemical Society.

[27]  F. Blanc,et al.  Alkane Metathesis Catalyzed by a Well‐Defined Silica‐Supported Mo Imido Alkylidene Complex: [(SiO)Mo(NAr)(CHtBu)(CH2tBu)] , 2006 .

[28]  F. Quignard,et al.  Catalytic Cleavage of the C-H and C-C Bonds of Alkanes by Surface Organometallic Chemistry: An EXAFS and IR Characterization of a Zr-H Catalyst , 1996, Science.

[29]  Glenn J. Sunley,et al.  Primary products and mechanistic considerations in alkane metathesis. , 2005, Journal of the American Chemical Society.

[30]  C. Santini,et al.  Synthesis, characterization, and activity in ethylene polymerization of silica supported cationic cyclopentadienyl zirconium complexes. , 2006, Journal of the American Chemical Society.

[31]  Par Jean‐Louis Hérisson,et al.  Catalyse de transformation des oléfines par les complexes du tungstène. II. Télomérisation des oléfines cycliques en présence d'oléfines acycliques , 1971 .

[32]  W. A. Nugent,et al.  Catalytic C-H activation in early transition-metal dialkylamides and alkoxides , 1983 .

[33]  C. Copéret,et al.  Metathesis of alkanes and related reactions. , 2010, Accounts of chemical research.

[34]  K. Szeto,et al.  High selectivity production of propylene from 2-butene: non-degenerate pathways to convert symmetric olefins via olefin metathesis. , 2012, Chemical Communications.

[35]  Manoja K. Samantaray,et al.  Controlling the hydrogenolysis of silica-supported tungsten pentamethyl leads to a class of highly electron deficient partially alkylated metal hydrides , 2015, Chemical science.

[36]  H. Taylor The Heterogeneity of Catalyst Surfaces for Chemisorption , 1948 .

[37]  V. Dufaud,et al.  Catalytic Hydrogenolysis at Low Temperature and Pressure of Polyethylene and Polypropylene to Diesels or Lower Alkanes by a Zirconium Hydride Supported on Silica-Alumina: A Step Toward Polyolefin Degradation by the Microscopic Reverse of Ziegler-Natta Polymerization. , 1998, Angewandte Chemie.