Metal-Organic Frameworks Mediate Cu Coordination for Selective CO2 Electroreduction.

The electrochemical carbon dioxide reduction reaction (CO2RR) produces diverse chemical species. Cu clusters with a judiciously controlled surface coordination number (CN) provide active sites that simultaneously optimize selectivity, activity, and efficiency for CO2RR. Here we report a strategy involving metal-organic framework (MOF)-regulated Cu cluster formation that shifts CO2 electroreduction toward multiple-carbon product generation. Specifically, we promoted undercoordinated sites during the formation of Cu clusters by controlling the structure of the Cu dimer, the precursor for Cu clusters. We distorted the symmetric paddle-wheel Cu dimer secondary building block of HKUST-1 to an asymmetric motif by separating adjacent benzene tricarboxylate moieties using thermal treatment. By varying materials processing conditions, we modulated the asymmetric local atomic structure, oxidation state and bonding strain of Cu dimers. Using electron paramagnetic resonance (EPR) and in situ X-ray absorption spectroscopy (XAS) experiments, we observed the formation of Cu clusters with low CN from distorted Cu dimers in HKUST-1 during CO2 electroreduction. These exhibited 45% C2H4 faradaic efficiency (FE), a record for MOF-derived Cu cluster catalysts. A structure-activity relationship was established wherein the tuning of the Cu-Cu CN in Cu clusters determines the CO2RR selectivity.

[1]  R. Quintero‐Bermudez,et al.  Steering post-C–C coupling selectivity enables high efficiency electroreduction of carbon dioxide to multi-carbon alcohols , 2018, Nature Catalysis.

[2]  Christine M. Gabardo,et al.  CO2 electroreduction to ethylene via hydroxide-mediated copper catalysis at an abrupt interface , 2018, Science.

[3]  O. Yaghi,et al.  The role of reticular chemistry in the design of CO2 reduction catalysts , 2018, Nature Materials.

[4]  Yang Liu,et al.  Mixed matrix formulations with MOF molecular sieving for key energy-intensive separations , 2018, Nature Materials.

[5]  Michael B. Ross,et al.  Catalyst electro-redeposition controls morphology and oxidation state for selective carbon dioxide reduction , 2018, Nature Catalysis.

[6]  Ke R. Yang,et al.  Active sites of copper-complex catalytic materials for electrochemical carbon dioxide reduction , 2018, Nature Communications.

[7]  Christopher J. Chang,et al.  Reticular Electronic Tuning of Porphyrin Active Sites in Covalent Organic Frameworks for Electrocatalytic Carbon Dioxide Reduction. , 2018, Journal of the American Chemical Society.

[8]  Huamin Zhang,et al.  Selective Electrochemical Reduction of Carbon Dioxide Using Cu Based Metal Organic Framework for CO2 Capture. , 2018, ACS applied materials & interfaces.

[9]  Jin-Xun Liu,et al.  Optimum Cu nanoparticle catalysts for CO2 hydrogenation towards methanol , 2018 .

[10]  Teruhiko Saito,et al.  Crystalline Copper(II) Phthalocyanine Catalysts for Electrochemical Reduction of Carbon Dioxide in Aqueous Media , 2017 .

[11]  K. Yi,et al.  Gaseous Nanocarving‐Mediated Carbon Framework with Spontaneous Metal Assembly for Structure‐Tunable Metal/Carbon Nanofibers , 2017, Advanced materials.

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

[13]  T. Jaramillo,et al.  Engineering Cu surfaces for the electrocatalytic conversion of CO2: Controlling selectivity toward oxygenates and hydrocarbons , 2017, Proceedings of the National Academy of Sciences.

[14]  Garikoitz Beobide,et al.  Copper-Based Metal-Organic Porous Materials for CO2 Electrocatalytic Reduction to Alcohols. , 2017, ChemSusChem.

[15]  Pengxin Liu,et al.  Surface Coordination Chemistry of Metal Nanomaterials. , 2017, Journal of the American Chemical Society.

[16]  Sung Jae Kim,et al.  Morphology-Directed Selective Production of Ethylene or Ethane from CO2 on a Cu Mesopore Electrode. , 2017, Angewandte Chemie.

[17]  Zhonglong Zhao,et al.  Generalized Surface Coordination Number as an Activity Descriptor for CO2 Reduction on Cu Surfaces , 2016 .

[18]  M. Cannas,et al.  Investigation by Raman Spectroscopy of the Decomposition Process of HKUST-1 upon Exposure to Air , 2016 .

[19]  Oleksandr Voznyy,et al.  Enhanced electrocatalytic CO2 reduction via field-induced reagent concentration , 2016, Nature.

[20]  E. Stach,et al.  Highly selective plasma-activated copper catalysts for carbon dioxide reduction to ethylene , 2016, Nature Communications.

[21]  V. Batista,et al.  Electrochemical CO2 Reduction to Hydrocarbons on a Heterogeneous Molecular Cu Catalyst in Aqueous Solution. , 2016, Journal of the American Chemical Society.

[22]  M. Cannas,et al.  Decomposition Process of Carboxylate MOF HKUST-1 Unveiled at the Atomic Scale Level , 2016, 1704.01008.

[23]  K. Jiang,et al.  A Direct Grain-Boundary-Activity Correlation for CO Electroreduction on Cu Nanoparticles , 2016, ACS central science.

[24]  Hyung J. Kim,et al.  Molecular Interactions of a Cu-Based Metal-Organic Framework with a Confined Imidazolium-Based Ionic Liquid : A Combined Density Functional Theory and Experimental Vibrational Spectroscopy Study , 2016 .

[25]  P. Yang,et al.  Metal-organic frameworks for electrocatalytic reduction of carbon dioxide. , 2015, Journal of the American Chemical Society.

[26]  Philippe Sautet,et al.  Finding optimal surface sites on heterogeneous catalysts by counting nearest neighbors , 2015, Science.

[27]  P. Yang,et al.  Covalent organic frameworks comprising cobalt porphyrins for catalytic CO2 reduction in water , 2015, Science.

[28]  A. Paul Alivisatos,et al.  Enhanced electrochemical methanation of carbon dioxide with a dispersible nanoscale copper catalyst. , 2014, Journal of the American Chemical Society.

[29]  Peter Strasser,et al.  Particle size effects in the catalytic electroreduction of CO₂ on Cu nanoparticles. , 2014, Journal of the American Chemical Society.

[30]  K. Zhou,et al.  MOF-templated formation of porous CuO hollow octahedra for lithium-ion battery anode materials , 2013 .

[31]  O. Shekhah,et al.  Defects in MOFs: a thorough characterization. , 2012, Chemphyschem : a European journal of chemical physics and physical chemistry.

[32]  Shu-fen Li,et al.  Study on thermal decomposition of copper(II) acetate monohydrate in air , 2012, Journal of Thermal Analysis and Calorimetry.

[33]  Andrea R. Gerson,et al.  Resolving surface chemical states in XPS analysis of first row transition metals, oxides and hydroxides: Sc, Ti, V, Cu and Zn , 2010 .

[34]  Rizwan Ahmad,et al.  Theory, instrumentation, and applications of electron paramagnetic resonance oximetry. , 2010, Chemical reviews.

[35]  C. Lamberti,et al.  Local Structure of Framework Cu(II) in HKUST-1 Metallorganic Framework: Spectroscopic Characterization upon Activation and Interaction with Adsorbates , 2006 .

[36]  Cher Ming Tan,et al.  Preparation and characterization of copper oxide thin films deposited by filtered cathodic vacuum arc , 2004 .

[37]  Michael O'Keeffe,et al.  Systematic Design of Pore Size and Functionality in Isoreticular MOFs and Their Application in Methane Storage , 2002, Science.

[38]  Ian D. Williams,et al.  A chemically functionalizable nanoporous material (Cu3(TMA)2(H2O)3)n , 1999 .