Catalysts by pyrolysis: Transforming metal-organic frameworks (MOFs) precursors into metal-nitrogen-carbon (M-N-C) materials

[1]  Zhiqun Lin,et al.  Collaborative integration of ultrafine Fe2P nanocrystals into Fe, N, P-codoped carbon nanoshells for highly-efficient oxygen reduction , 2023, Nano Energy.

[2]  M. Zachman,et al.  Atomically dispersed iron sites with a nitrogen–carbon coating as highly active and durable oxygen reduction catalysts for fuel cells , 2022, Nature Energy.

[3]  C. C. Dey,et al.  Temperature induced phase transformation in Co , 2022, Scientific Reports.

[4]  Wenhui Hu,et al.  Postsynthetic Treatment of ZIF-67 with 5-Methyltetrazole: Evolution from Pseudo-Td to Pseudo-Oh Symmetry and Collapse of Magnetic Ordering. , 2022, Inorganic chemistry.

[5]  J. Gustafson,et al.  Structural Changes in Monolayer Cobalt Oxides under Ambient Pressure CO and O2 Studied by In Situ Grazing-Incidence X-ray Absorption Fine Structure Spectroscopy , 2022, The journal of physical chemistry. C, Nanomaterials and interfaces.

[6]  Juan-Ding Xiao,et al.  Modulating acid-base properties of ZIF-8 by thermal-induced structure evolution , 2022, Journal of Catalysis.

[7]  Viktor V. Nikitin,et al.  Fast X‐ray Nanotomography with Sub‐10 nm Resolution as a Powerful Imaging Tool for Nanotechnology and Energy Storage Applications , 2021, Advanced materials.

[8]  Jianfeng Chen,et al.  Exploring the Roles of ZIF-67 as an Energetic Additive in the Thermal Decomposition of Ammonium Perchlorate , 2021 .

[9]  T. Bennett,et al.  Ionic liquid facilitated melting of the metal-organic framework ZIF-8 , 2021, Nature Communications.

[10]  A. Gurlo,et al.  Steering the Methane Dry Reforming Reactivity of Ni/La2O3 Catalysts by Controlled In Situ Decomposition of Doped La2NiO4 Precursor Structures , 2020, ACS catalysis.

[11]  Qiang Sun,et al.  Chemical vapour deposition of Fe–N–C oxygen reduction catalysts with full utilization of dense Fe–N4 sites , 2020, Nature Materials.

[12]  Xing Li,et al.  Atomically Dispersed MnN4 Catalysts via Environmentally Benign Aqueous Synthesis for Oxygen Reduction: Mechanistic Understanding of Activity and Stability Improvements , 2020 .

[13]  A. Kulikovsky,et al.  Electron and proton conductivity of Fe-N-C cathodes for PEM fuel cells: A model-based electrochemical impedance spectroscopy measurement , 2020 .

[14]  Yupo J. Lin,et al.  Capacitive deionization using carbon derived from an array of zeolitic-imidazolate frameworks , 2020 .

[15]  D. Sun-Waterhouse,et al.  Evolution of Zn(II) single atom catalyst sites during the pyrolysis-induced transformation of ZIF-8 to N-doped carbons. , 2020, Science bulletin.

[16]  R. Behm,et al.  Synthesis of amorphous and graphitized porous nitrogen-doped carbon spheres as oxygen reduction reaction catalysts , 2020, Beilstein journal of nanotechnology.

[17]  Evan C. Wegener,et al.  The evolution pathway from iron compounds to Fe1(II)-N4 sites through gas-phase iron during pyrolysis. , 2019, Journal of the American Chemical Society.

[18]  M. Fontecave,et al.  Electroreduction of CO2 on Single-Site Copper-Nitrogen-Doped Carbon Material: Selective Formation of Ethanol and Reversible Restructuration of the Metal Sites. , 2019, Angewandte Chemie.

[19]  David A. Hardy,et al.  Prussian Blue Iron–Cobalt Mesocrystals as a Template for the Growth of Fe/Co Carbide (Cementite) and Fe/Co Nanocrystals , 2019, Chemistry of Materials.

[20]  C. Santoro,et al.  Correlations between Synthesis and Performance of Fe-Based PGM-Free Catalysts in Acidic and Alkaline Media: Evolution of Surface Chemistry and Morphology , 2019, ACS Applied Energy Materials.

[21]  J. Baek,et al.  Identifying the structure of Zn-N2 active sites and structural activation , 2019, Nature Communications.

[22]  D. Cullen,et al.  Atomically dispersed manganese catalysts for oxygen reduction in proton-exchange membrane fuel cells , 2018, Nature Catalysis.

[23]  K. Artyushkova,et al.  Mechanism of Oxygen Reduction Reaction on Transition Metal–Nitrogen–Carbon Catalysts: Establishing the Role of Nitrogen-containing Active Sites , 2018, ACS Applied Energy Materials.

[24]  K. Artyushkova,et al.  Understanding PGM-free catalysts by linking density functional theory calculations and structural analysis: Perspectives and challenges , 2018, Current Opinion in Electrochemistry.

[25]  A. Gurlo,et al.  Transmission in situ and operando high temperature X-ray powder diffraction in variable gaseous environments. , 2018, The Review of scientific instruments.

[26]  Liming Dai,et al.  Novel MOF‐Derived Co@N‐C Bifunctional Catalysts for Highly Efficient Zn–Air Batteries and Water Splitting , 2018, Advanced materials.

[27]  F. Prinz,et al.  Revealing the Bonding Environment of Zn in ALD Zn(O,S) Buffer Layers through X-ray Absorption Spectroscopy , 2017, ACS applied materials & interfaces.

[28]  Karren L. More,et al.  Direct atomic-level insight into the active sites of a high-performance PGM-free ORR catalyst , 2017, Science.

[29]  Michael J. Workman,et al.  Fe–N–C Catalyst Graphitic Layer Structure and Fuel Cell Performance , 2017 .

[30]  J. Carrasco,et al.  Atomic-level energy storage mechanism of cobalt hydroxide electrode for pseudocapacitors , 2017, Nature Communications.

[31]  Wei Xia,et al.  High-Performance Energy Storage and Conversion Materials Derived from a Single Metal-Organic Framework/Graphene Aerogel Composite. , 2017, Nano letters.

[32]  A. Gurlo,et al.  Compact low power infrared tube furnace for in situ X-ray powder diffraction. , 2017, The Review of scientific instruments.

[33]  K. Artyushkova,et al.  Core Level Shifts of Hydrogenated Pyridinic and Pyrrolic Nitrogen in the Nitrogen-Containing Graphene-Based Electrocatalysts: In-Plane vs Edge Defects , 2016 .

[34]  Xiaoyi Zhang,et al.  Exceptionally Long-Lived Charge Separated State in Zeolitic Imidazolate Framework: Implication for Photocatalytic Applications. , 2016, Journal of the American Chemical Society.

[35]  Sung-Fu Hung,et al.  In Operando Identification of Geometrical-Site-Dependent Water Oxidation Activity of Spinel Co3O4. , 2016, Journal of the American Chemical Society.

[36]  S. V. D. Perre,et al.  Adsorption and Diffusion Phenomena in Crystal Size Engineered ZIF-8 MOF , 2015 .

[37]  Edward F. Holby,et al.  Experimental Observation of Redox-Induced Fe-N Switching Behavior as a Determinant Role for Oxygen Reduction Activity. , 2015, ACS nano.

[38]  K. Artyushkova,et al.  Chemistry of Multitudinous Active Sites for Oxygen Reduction Reaction in Transition Metal–Nitrogen–Carbon Electrocatalysts , 2015 .

[39]  Frédéric Jaouen,et al.  Identification of catalytic sites for oxygen reduction in iron- and nitrogen-doped graphene materials. , 2015, Nature materials.

[40]  K. Artyushkova,et al.  Nano-structured non-platinum catalysts for automotive fuel cell application , 2015 .

[41]  V. Prakapenka,et al.  DIOPTAS: a program for reduction of two-dimensional X-ray diffraction data and data exploration , 2015 .

[42]  S. Mukerjee,et al.  Highly active oxygen reduction non-platinum group metal electrocatalyst without direct metal–nitrogen coordination , 2015, Nature Communications.

[43]  J. Eckert,et al.  Direct in situ observations of single Fe atom catalytic processes and anomalous diffusion at graphene edges , 2014, Proceedings of the National Academy of Sciences.

[44]  P. Atanassov,et al.  Elucidating Oxygen Reduction Active Sites in Pyrolyzed Metal–Nitrogen Coordinated Non-Precious-Metal Electrocatalyst Systems , 2014, The journal of physical chemistry. C, Nanomaterials and interfaces.

[45]  M. Batzill,et al.  Graphene-nickel interfaces: a review. , 2014, Nanoscale.

[46]  Michael H. Robson,et al.  Tri-metallic transition metal–nitrogen–carbon catalysts derived by sacrificial support method synthesis , 2013 .

[47]  K. Artyushkova,et al.  Density functional theory calculations of XPS binding energy shift for nitrogen-containing graphene-like structures. , 2013, Chemical communications.

[48]  J. Baldwin,et al.  Nitrogen-doped graphene-rich catalysts derived from heteroatom polymers for oxygen reduction in nonaqueous lithium-O2 battery cathodes. , 2012, ACS nano.

[49]  S. Mukerjee,et al.  Structure of the catalytic sites in Fe/N/C-catalysts for O2-reduction in PEM fuel cells. , 2012, Physical chemistry chemical physics : PCCP.

[50]  Juan Herranz,et al.  Iron-based cathode catalyst with enhanced power density in polymer electrolyte membrane fuel cells. , 2011, Nature communications.

[51]  Gang Wu,et al.  High-Performance Electrocatalysts for Oxygen Reduction Derived from Polyaniline, Iron, and Cobalt , 2011, Science.

[52]  J. Jasinski,et al.  Structural evolution of zeolitic imidazolate framework-8. , 2010, Journal of the American Chemical Society.

[53]  G. Flynn,et al.  Structure and electronic properties of graphene nanoislands on Co(0001). , 2009, Nano letters.

[54]  Frédéric Jaouen,et al.  Iron-Based Catalysts with Improved Oxygen Reduction Activity in Polymer Electrolyte Fuel Cells , 2009, Science.

[55]  M. Dresselhaus,et al.  Raman spectroscopy in graphene , 2009 .

[56]  Michael O'Keeffe,et al.  High-Throughput Synthesis of Zeolitic Imidazolate Frameworks and Application to CO2 Capture , 2008, Science.

[57]  Michael O’Keeffe,et al.  Exceptional chemical and thermal stability of zeolitic imidazolate frameworks , 2006, Proceedings of the National Academy of Sciences.

[58]  Reinhard Niessner,et al.  Raman microspectroscopy of soot and related carbonaceous materials: Spectral analysis and structural information , 2005 .

[59]  M. Dresselhaus,et al.  Formation of graphitic structures in cobalt- and nickel-doped carbon aerogels. , 2005, Langmuir : the ACS journal of surfaces and colloids.

[60]  T. Guo,et al.  Investigation of Co nanoparticles with EXAFS and XANES , 2004 .

[61]  F. Wachi,et al.  Vapor Pressure and Heat of Vaporization of Cobalt , 1972 .

[62]  R. Jasinski,et al.  A New Fuel Cell Cathode Catalyst , 1964, Nature.

[63]  Sotiris E. Pratsinis,et al.  Monte Carlo simulation of particle coagulation and sintering , 1994 .

[64]  A. Ōya,et al.  Catalytic graphitization of carbons by various metals , 1979 .

[65]  A. H. Cook 325. Catalytic properties of the phthalocyanines. Part I. Catalase properties , 1938 .