Well‐Dispersed Nickel‐ and Zinc‐Tailored Electronic Structure of a Transition Metal Oxide for Highly Active Alkaline Hydrogen Evolution Reaction

The practical scale‐up of renewable energy technologies will require catalysts that are more efficient and durable than present ones. This is, however, a formidable challenge that will demand a new capability to tailor the electronic structure. Here, an original electronic structure tailoring of CoO by Ni and Zn dual doping is reported. This changes it from an inert material into one that is highly active for the hydrogen evolution reaction (HER). Based on combined density functional theory calculations and cutting‐edge characterizations, it is shown that dual Ni and Zn doping is responsible for a highly significant increase in HER activity of the host oxide. That is, the Ni dopants cluster around surface oxygen vacancy of the host oxide and provide an ideal electronic surface structure for hydrogen intermediate binding, while the Zn dopants distribute inside the host oxide and modulate the bulk electronic structure to boost electrical conduction. As a result, the dual‐doped Ni, Zn CoO nanorods achieve current densities of 10 and 20 mA cm−2 at overpotentials of, respectively, 53 and 79 mV. This outperforms reported state‐of‐the‐art metal oxide, metal oxide/metal, metal sulfide, and metal phosphide catalysts.

[1]  Xi‐Wen Du,et al.  Multiscale Structural Engineering of Ni‐Doped CoO Nanosheets for Zinc–Air Batteries with High Power Density , 2018, Advanced materials.

[2]  M. Jaroniec,et al.  Atomic-level structure engineering of metal oxides for high-rate oxygen intercalation pseudocapacitance , 2018, Science Advances.

[3]  Yuan Ha,et al.  Ultrafine Co Nanoparticles Encapsulated in Carbon‐Nanotubes‐Grafted Graphene Sheets as Advanced Electrocatalysts for the Hydrogen Evolution Reaction , 2018, Advanced materials.

[4]  M. Jaroniec,et al.  Activating cobalt(II) oxide nanorods for efficient electrocatalysis by strain engineering , 2017, Nature Communications.

[5]  Tao Ling,et al.  Atomically and Electronically Coupled Pt and CoO Hybrid Nanocatalysts for Enhanced Electrocatalytic Performance , 2017, Advanced materials.

[6]  M. Jaroniec,et al.  High Electrocatalytic Hydrogen Evolution Activity of an Anomalous Ruthenium Catalyst. , 2016, Journal of the American Chemical Society.

[7]  Tao Ling,et al.  Engineering surface atomic structure of single-crystal cobalt (II) oxide nanorods for superior electrocatalysis , 2016, Nature Communications.

[8]  Xiaodong Zhuang,et al.  Engineering water dissociation sites in MoS2 nanosheets for accelerated electrocatalytic hydrogen production , 2016 .

[9]  Shui-Tong Lee,et al.  A rhodium/silicon co-electrocatalyst design concept to surpass platinum hydrogen evolution activity at high overpotentials , 2016, Nature Communications.

[10]  A. Hirata,et al.  Versatile nanoporous bimetallic phosphides towards electrochemical water splitting , 2016 .

[11]  Thomas F. Jaramillo,et al.  Gold-supported cerium-doped NiOx catalysts for water oxidation , 2016, Nature Energy.

[12]  A. Vojvodić,et al.  Homogeneously dispersed multimetal oxygen-evolving catalysts , 2016, Science.

[13]  Feng Li,et al.  Metal/Oxide Interface Nanostructures Generated by Surface Segregation for Electrocatalysis. , 2015, Nano letters.

[14]  Xiaobo Chen,et al.  Three-Dimensional Crystalline/Amorphous Co/Co3O4 Core/Shell Nanosheets as Efficient Electrocatalysts for the Hydrogen Evolution Reaction. , 2015, Nano letters.

[15]  Yayuan Liu,et al.  Bifunctional non-noble metal oxide nanoparticle electrocatalysts through lithium-induced conversion for overall water splitting , 2015, Nature Communications.

[16]  M. V. Ganduglia-Pirovano,et al.  In situ and theoretical studies for the dissociation of water on an active Ni/CeO2 catalyst: importance of strong metal-support interactions for the cleavage of O-H bonds. , 2015, Angewandte Chemie.

[17]  Z. Tang,et al.  Ultrathin platinum nanowires grown on single-layered nickel hydroxide with high hydrogen evolution activity , 2015, Nature Communications.

[18]  Xi‐Wen Du,et al.  Gas-Phase Cation Exchange toward Porous Single-Crystal CoO Nanorods for Catalytic Hydrogen Production , 2015 .

[19]  Yao Zheng,et al.  Advancing the electrochemistry of the hydrogen-evolution reaction through combining experiment and theory. , 2015, Angewandte Chemie.

[20]  Mietek Jaroniec,et al.  Metal-organic framework derived hybrid Co3O4-carbon porous nanowire arrays as reversible oxygen evolution electrodes. , 2014, Journal of the American Chemical Society.

[21]  Yongfeng Hu,et al.  Nanoscale nickel oxide/nickel heterostructures for active hydrogen evolution electrocatalysis , 2014, Nature Communications.

[22]  Nemanja Danilovic,et al.  Functional links between stability and reactivity of strontium ruthenate single crystals during oxygen evolution , 2014, Nature Communications.

[23]  Zheng Chang,et al.  Hierarchical ZnxCo3–xO4 Nanoarrays with High Activity for Electrocatalytic Oxygen Evolution , 2014 .

[24]  Yang Shao-Horn,et al.  Double perovskites as a family of highly active catalysts for oxygen evolution in alkaline solution , 2013, Nature Communications.

[25]  Guosong Hong,et al.  Advanced zinc-air batteries based on high-performance hybrid electrocatalysts , 2013, Nature Communications.

[26]  D. Stolten,et al.  A comprehensive review on PEM water electrolysis , 2013 .

[27]  Jun Chen,et al.  Enhancing electrocatalytic oxygen reduction on MnO(2) with vacancies. , 2013, Angewandte Chemie.

[28]  P. Jain,et al.  Cation exchange on the nanoscale: an emerging technique for new material synthesis, device fabrication, and chemical sensing. , 2013, Chemical Society reviews.

[29]  James R. McKone,et al.  Ni–Mo Nanopowders for Efficient Electrochemical Hydrogen Evolution , 2013 .

[30]  Jian Wang,et al.  Oxygen reduction electrocatalyst based on strongly coupled cobalt oxide nanocrystals and carbon nanotubes. , 2012, Journal of the American Chemical Society.

[31]  Jun Chen,et al.  Metal-air batteries: from oxygen reduction electrochemistry to cathode catalysts. , 2012, Chemical Society reviews.

[32]  J. Goodenough,et al.  A Perovskite Oxide Optimized for Oxygen Evolution Catalysis from Molecular Orbital Principles , 2011, Science.

[33]  V. Stamenkovic,et al.  Enhancing Hydrogen Evolution Activity in Water Splitting by Tailoring Li+-Ni(OH)2-Pt Interfaces , 2011, Science.

[34]  H. Dai,et al.  Co₃O₄ nanocrystals on graphene as a synergistic catalyst for oxygen reduction reaction. , 2011, Nature materials.

[35]  J. Goodenough,et al.  Design principles for oxygen-reduction activity on perovskite oxide catalysts for fuel cells and metal-air batteries. , 2011, Nature chemistry.

[36]  James R. McKone,et al.  Solar water splitting cells. , 2010, Chemical reviews.

[37]  Timothy R. Cook,et al.  Solar energy supply and storage for the legacy and nonlegacy worlds. , 2010, Chemical reviews.

[38]  Ru‐Shi Liu,et al.  O-K and Co-L XANES Study on Oxygen Intercalation in Perovskite SrCoO3-δ , 2010 .

[39]  J. Nørskov,et al.  Towards the computational design of solid catalysts. , 2009, Nature chemistry.

[40]  Jianli Hu,et al.  An overview of hydrogen production technologies , 2009 .

[41]  Ziyu Wu,et al.  Evidence of substitutional Co ion clusters inZn1−xCoxOdilute magnetic semiconductors , 2008 .

[42]  Lin-Wang Wang,et al.  Spontaneous Superlattice Formation in Nanorods Through Partial Cation Exchange , 2007, Science.

[43]  M. Winter,et al.  What are batteries, fuel cells, and supercapacitors? , 2004, Chemical reviews.

[44]  Charlie Tsai,et al.  Activating and optimizing MoS2 basal planes for hydrogen evolution through the formation of strained sulphur vacancies. , 2016, Nature materials.

[45]  B. Hwang,et al.  A mini review on nickel-based electrocatalysts for alkaline hydrogen evolution reaction , 2015, Nano Research.

[46]  Zhenhai Xia,et al.  A metal-free bifunctional electrocatalyst for oxygen reduction and oxygen evolution reactions. , 2015, Nature nanotechnology.