Unexpected "Spontaneous" Evolution of Catalytic, MOF-Supported Single Cu(II) Cations to Catalytic, MOF-Supported Cu(0) Nanoparticles.

A desirable feature of metal-organic frameworks (MOFs) is their well-defined structural periodicity and the presence of well-defined catalyst grafting sites (e.g., reactive -OH and -OH2 groups) that can support single-site heterogeneous catalysts. However, one should not overlook the potential role of residual organic moieties, specifically formate ions that can occupy the catalyst anchoring sites during MOF synthesis. Here we show how these residual formate species in a Zr-based MOF, NU-1000, critically alter the structure, redox capability, and catalytic activity of postsynthetically incorporated Cu(II) ions. Single-crystal X-ray diffraction measurements established that there are two structurally distinct types of Cu(II) ions in NU-1000: one type with residual formate and one without. In NU-1000 with formate, Cu(II) solely binds to the node via the formate-unoccupied, bridging μ3-OH, whereas in the formate-free case, it displaces protons from two node hydroxo ligands and resides close to the terminal -OH2. Under an inert atmosphere, node-bound formate facilitates the unanticipated reduction of isolated Cu(II) to nanoparticulate Cu(0)-a behavior which is essentially absent in the formate-free analogue because no other sacrificial reductant is present. When the two MOFs were tested as benzyl alcohol oxidation catalysts, we observed that residual formate boosts the catalytic turnover frequency. Density functional calculations showed that node-bound formate acts as a sacrificial two-electron donor and assists in reducing Cu(II) to Cu(0) by a nonradical pathway. The negative Gibbs free energy of reaction (ΔG) and enthalpy of reaction (ΔH) indicate that the reduction is thermodynamically favorable. The work presented here highlights how the often-neglected residual formate prevalent in nearly all zirconium-based MOFs can significantly modulate the properties of supported catalysts.

[1]  J. Hupp,et al.  Node-Accessible Zirconium MOFs. , 2020, Journal of the American Chemical Society.

[2]  L. Cavallo,et al.  Extension of the Surface Organometallic Chemistry to Metal-Organic Framework: development of well-defined single site [(≡Zr-O-)W(=O)(CH2tBu)3] olefin metathesis catalyst. , 2020, Journal of the American Chemical Society.

[3]  Yingwei Li,et al.  Metal–Organic Frameworks as a Good Platform for the Fabrication of Single-Atom Catalysts , 2020 .

[4]  J. Gascón,et al.  Metal-Organic Frameworks in Heterogeneous Catalysis: Recent Progress, New Trends, and Future Perspectives. , 2020, Chemical reviews.

[5]  O. Farha,et al.  Precise Control of Cu Nanoparticle Size and Catalytic Activity through Pore Templating in Zr Metal–Organic Frameworks , 2020 .

[6]  Dmitry I. Sharapa,et al.  Interplay of Electronic and Steric Effects to Yield Low‐Temperature CO Oxidation at Metal Single Sites in Defect‐Engineered HKUST‐1 , 2020, Angewandte Chemie.

[7]  J. Hupp,et al.  Structural reversibility of Cu doped NU-1000 MOFs under hydrogenation conditions. , 2020, The Journal of chemical physics.

[8]  Zoha H. Syed,et al.  Single‐Site, Single‐Metal‐Atom, Heterogeneous Electrocatalyst: Metal–Organic‐Framework Supported Molybdenum Sulfide for Redox Mediator‐Assisted Hydrogen Evolution Reaction , 2020 .

[9]  Seth M. Cohen,et al.  MOF-Polymer Hybrid Materials: From Simple Composites to Tailored Architectures. , 2020, Chemical reviews.

[10]  Nicolaas A. Vermeulen,et al.  The Synthesis Science of Targeted Vapor-Phase Metal-Organic Framework Postmodification. , 2019, Journal of the American Chemical Society.

[11]  B. L. Mehdi,et al.  Selective Methane Oxidation to Methanol on Cu-Oxo Dimers Stabilized by Zirconia Nodes of an NU-1000 Metal-Organic Framework. , 2019, Journal of the American Chemical Society.

[12]  M. Wasielewski,et al.  Vanadium Catalyst on Isostructural Transition Metal, Lanthanide, and Actinide Based Metal-Organic Frameworks for Alcohol Oxidation. , 2019, Journal of the American Chemical Society.

[13]  David J. Mandia,et al.  Introducing Nonstructural Ligands to Zirconia-like Metal–Organic Framework Nodes To Tune the Activity of Node-Supported Nickel Catalysts for Ethylene Hydrogenation , 2019, ACS Catalysis.

[14]  C. Cramer,et al.  Tuning the Properties of Zr6O8 Nodes in the Metal Organic Framework UiO-66 by Selection of Node-Bound Ligands and Linkers , 2019, Chemistry of Materials.

[15]  J. Hupp,et al.  Metal–Organic Framework Supported Single Site Chromium(III) Catalyst for Ethylene Oligomerization at Low Pressure and Temperature , 2019, ACS Sustainable Chemistry & Engineering.

[16]  J. Hupp,et al.  Redox-Mediator-Assisted Electrocatalytic Hydrogen Evolution from Water by a Molybdenum Sulfide-Functionalized Metal–Organic Framework , 2018, ACS Catalysis.

[17]  Baoxiang Peng,et al.  CuPd Mixed-Metal HKUST-1 as a Catalyst for Aerobic Alcohol Oxidation , 2018, The Journal of Physical Chemistry C.

[18]  Wenbin Lin,et al.  Site Isolation in Metal-Organic Frameworks Enables Novel Transition Metal Catalysis. , 2018, Accounts of chemical research.

[19]  J. Hupp,et al.  Single-Atom-Based Vanadium Oxide Catalysts Supported on Metal-Organic Frameworks: Selective Alcohol Oxidation and Structure-Activity Relationship. , 2018, Journal of the American Chemical Society.

[20]  C. Wöll,et al.  Chemical Reactions at Isolated Single-Sites Inside Metal–Organic Frameworks , 2018, Catalysis Letters.

[21]  M. A. Ortuño,et al.  Structure and Dynamics of Zr6O8 Metal-Organic Framework Node Surfaces Probed with Ethanol Dehydration as a Catalytic Test Reaction. , 2018, Journal of the American Chemical Society.

[22]  Donald G. Truhlar,et al.  Computational Design of Functionalized Metal–Organic Framework Nodes for Catalysis , 2017, ACS central science.

[23]  J. Hupp,et al.  Copper Nanoparticles Installed in Metal–Organic Framework Thin Films are Electrocatalytically Competent for CO2 Reduction , 2017 .

[24]  Haoyu S. Yu,et al.  Revised M06-L functional for improved accuracy on chemical reaction barrier heights, noncovalent interactions, and solid-state physics , 2017, Proceedings of the National Academy of Sciences.

[25]  B. L. Mehdi,et al.  Methane Oxidation to Methanol Catalyzed by Cu-Oxo Clusters Stabilized in NU-1000 Metal-Organic Framework. , 2017, Journal of the American Chemical Society.

[26]  Yang Song,et al.  Single-Site Cobalt Catalysts at New Zr12(μ3-O)8(μ3-OH)8(μ2-OH)6 Metal-Organic Framework Nodes for Highly Active Hydrogenation of Nitroarenes, Nitriles, and Isocyanides. , 2017, Journal of the American Chemical Society.

[27]  D. Palagin,et al.  Selective anaerobic oxidation of methane enables direct synthesis of methanol , 2017, Science.

[28]  N. Stock,et al.  Synthesis and Characterization of New Ce(IV)-MOFs Exhibiting Various Framework Topologies , 2017 .

[29]  M. A. Ortuño,et al.  Metal–Organic Framework Supported Cobalt Catalysts for the Oxidative Dehydrogenation of Propane at Low Temperature , 2016, ACS central science.

[30]  J. Hupp,et al.  Tuning the Surface Chemistry of Metal Organic Framework Nodes: Proton Topology of the Metal-Oxide-Like Zr6 Nodes of UiO-66 and NU-1000. , 2016, Journal of the American Chemical Society.

[31]  Diego A. Gómez-Gualdrón,et al.  Framework-Topology-Dependent Catalytic Activity of Zirconium-Based (Porphinato)zinc(II) MOFs. , 2016, Journal of the American Chemical Society.

[32]  Francis X. Greene,et al.  Single-Site Cobalt Catalysts at New Zr8(μ2-O)8(μ2-OH)4 Metal-Organic Framework Nodes for Highly Active Hydrogenation of Alkenes, Imines, Carbonyls, and Heterocycles. , 2016, Journal of the American Chemical Society.

[33]  Francis X. Greene,et al.  Chemoselective single-site Earth-abundant metal catalysts at metal–organic framework nodes , 2016, Nature Communications.

[34]  J. Hupp,et al.  Toward Inexpensive Photocatalytic Hydrogen Evolution: A Nickel Sulfide Catalyst Supported on a High-Stability Metal-Organic Framework. , 2016, ACS applied materials & interfaces.

[35]  Sachin Chavan,et al.  Defect Engineering: Tuning the Porosity and Composition of the Metal–Organic Framework UiO-66 via Modulated Synthesis , 2016 .

[36]  Jean-Marie Basset,et al.  Catalysis by Design: Well-Defined Single-Site Heterogeneous Catalysts. , 2016, Accounts of chemical research.

[37]  J. Hupp,et al.  Chemical, thermal and mechanical stabilities of metal–organic frameworks , 2016 .

[38]  Christophe Copéret,et al.  Surface Organometallic and Coordination Chemistry toward Single-Site Heterogeneous Catalysts: Strategies, Methods, Structures, and Activities. , 2016, Chemical reviews.

[39]  J. Hupp,et al.  Tuning Zr6 Metal–Organic Framework (MOF) Nodes as Catalyst Supports: Site Densities and Electron-Donor Properties Influence Molecular Iridium Complexes as Ethylene Conversion Catalysts , 2016 .

[40]  J. Hupp,et al.  Metal-Organic Framework Thin Films as Platforms for Atomic Layer Deposition of Cobalt Ions To Enable Electrocatalytic Water Oxidation. , 2015, ACS applied materials & interfaces.

[41]  Omar K Farha,et al.  Atomically Precise Growth of Catalytically Active Cobalt Sulfide on Flat Surfaces and within a Metal-Organic Framework via Atomic Layer Deposition. , 2015, ACS nano.

[42]  E. Hensen,et al.  Single-site trinuclear copper oxygen clusters in mordenite for selective conversion of methane to methanol , 2015, Nature Communications.

[43]  Nicolaas A. Vermeulen,et al.  A hafnium-based metal-organic framework as an efficient and multifunctional catalyst for facile CO2 fixation and regioselective and enantioretentive epoxide activation. , 2014, Journal of the American Chemical Society.

[44]  Joshua Borycz,et al.  Defining the Proton Topology of the Zr6-Based Metal-Organic Framework NU-1000. , 2014, The journal of physical chemistry letters.

[45]  J. Fraser Stoddart,et al.  Metal-organic framework thin films composed of free-standing acicular nanorods exhibiting reversible electrochromism , 2013 .

[46]  Michael O’Keeffe,et al.  The Chemistry and Applications of Metal-Organic Frameworks , 2013, Science.

[47]  David Fairen-Jimenez,et al.  Vapor-phase metalation by atomic layer deposition in a metal-organic framework. , 2013, Journal of the American Chemical Society.

[48]  S. Stahl,et al.  Mechanism of copper(I)/TEMPO-catalyzed aerobic alcohol oxidation. , 2013, Journal of the American Chemical Society.

[49]  B. Sels,et al.  Coordination chemistry and reactivity of copper in zeolites , 2013 .

[50]  Dawei Feng,et al.  Zirconium-metalloporphyrin PCN-222: mesoporous metal-organic frameworks with ultrahigh stability as biomimetic catalysts. , 2012, Angewandte Chemie.

[51]  R. Schlögl,et al.  In situ generation of active sites in olefin metathesis. , 2012, Journal of the American Chemical Society.

[52]  Duilio Cascio,et al.  Synthesis, structure, and metalation of two new highly porous zirconium metal-organic frameworks. , 2012, Inorganic chemistry.

[53]  Wenbin Lin,et al.  A series of isoreticular chiral metal-organic frameworks as a tunable platform for asymmetric catalysis. , 2010, Nature chemistry.

[54]  Dan Zhao,et al.  Potential applications of metal-organic frameworks , 2009 .

[55]  Hong-Cai Zhou,et al.  Selective gas adsorption and separation in metal-organic frameworks. , 2009, Chemical Society reviews.

[56]  Omar K Farha,et al.  Metal-organic framework materials as catalysts. , 2009, Chemical Society reviews.

[57]  Wenbin Lin,et al.  Enantioselective catalysis with homochiral metal-organic frameworks. , 2009, Chemical Society reviews.

[58]  Mircea Dincă,et al.  Hydrogen storage in metal-organic frameworks. , 2009, Chemical Society reviews.

[59]  Robert Raja,et al.  Single-site heterogeneous catalysts. , 2005, Angewandte Chemie.

[60]  Susumu Kitagawa,et al.  Functional porous coordination polymers. , 2004, Angewandte Chemie.

[61]  Agustín R. González-Elipe,et al.  Interface Effects for Cu, CuO, and Cu2O Deposited on SiO2 and ZrO2. XPS Determination of the Valence State of Copper in Cu/SiO2 and Cu/ZrO2 Catalysts , 2002 .

[62]  M. O'keeffe,et al.  Design and synthesis of an exceptionally stable and highly porous metal-organic framework , 1999, Nature.

[63]  W. Sachtler,et al.  Redox Chemistry of Cu/ZSM-5 , 1996 .

[64]  E. Iglesia,et al.  Decomposition of formic acid on copper, nickel, and copper-nickel alloys: II. Catalytic and temperature-programmed decomposition of formic acid on CuSiO2, CuAl2O3, and Cu powder , 1983 .