Reduced Mesoporous Co3O4 Nanowires as Efficient Water Oxidation Electrocatalysts and Supercapacitor Electrodes

While electrochemical water splitting is one of the most promising methods to store light/electrical energy in chemical bonds, a key challenge remains in the realization of an efficient oxygen evolution reaction catalyst with large surface area, good electrical conductivity, high catalytic properties, and low fabrication cost. Here, a facile solution reduction method is demonstrated for mesoporous Co3O4 nanowires treated with NaBH4. The high‐surface‐area mesopore feature leads to efficient surface reduction in solution at room temperature, which allows for retention of the nanowire morphology and 1D charge transport behavior, while at the same time substantially increasing the oxygen vacancies on the nanowire surface. Compared to pristine Co3O4 nanowires, the reduced Co3O4 nanowires exhibit a much larger current of 13.1 mA cm‐2 at 1.65 V vs reversible hydrogen electrode (RHE) and a much lower onset potential of 1.52 V vs RHE. Electrochemical supercapacitors based on the reduced Co3O4 nanowires also show a much improved capacitance of 978 F g‐1 and reduced charge transfer resistance. Density‐functional theory calculations reveal that the existence of oxygen vacancies leads to the formation of new gap states in which the electrons previously associated with the Co‐O bonds tend to be delocalized, resulting in the much higher electrical conductivity and electrocatalytic activity.

[1]  Bowen Zhu,et al.  A Mechanically and Electrically Self‐Healing Supercapacitor , 2014, Advanced materials.

[2]  Dongdong Qin,et al.  Reduced monoclinic BiVO₄ for improved photoelectrochemical oxidation of water under visible light. , 2014, Dalton transactions.

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

[4]  S. C. Parker,et al.  Rutile (β-)MnO2 surfaces and vacancy formation for high electrochemical and catalytic performance. , 2014, Journal of the American Chemical Society.

[5]  A. Frenkel,et al.  WGS catalysis and in situ studies of CoO(1-x), PtCo(n)/Co3O4, and Pt(m)Co(m')/CoO(1-x) nanorod catalysts. , 2013, Journal of the American Chemical Society.

[6]  B. Liu,et al.  A fully integrated nanosystem of semiconductor nanowires for direct solar water splitting. , 2013, Nano letters.

[7]  Jinhua Ye,et al.  Reduced TiO2 nanotube arrays for photoelectrochemical water splitting , 2013 .

[8]  H. Hng,et al.  Three-dimensional CdS-titanate composite nanomaterials for enhanced visible-light-driven hydrogen evolution. , 2013, Small.

[9]  Tongxiang Fan,et al.  Butterflies: inspiration for solar cells and sunlight water-splitting catalysts , 2012 .

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

[11]  X. Lou,et al.  Growth of ultrathin mesoporous Co3O4 nanosheet arrays on Ni foam for high-performance electrochemical capacitors , 2012 .

[12]  X. Lou,et al.  Porous Co3O4 nanowires derived from long Co(CO3)(0.5)(OH)·0.11H2O nanowires with improved supercapacitive properties. , 2012, Nanoscale.

[13]  G. Gary Wang,et al.  Hydrogen-treated WO3 nanoflakes show enhanced photostability , 2012 .

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

[15]  Yichuan Ling,et al.  Hydrogen-treated TiO2 nanowire arrays for photoelectrochemical water splitting. , 2011, Nano letters.

[16]  Xifan Wu,et al.  Electronic structure and bonding properties of cobalt oxide in the spinel structure , 2011, 1104.4383.

[17]  Xiaobo Chen,et al.  Increasing Solar Absorption for Photocatalysis with Black Hydrogenated Titanium Dioxide Nanocrystals , 2011, Science.

[18]  Matthew W Kanan,et al.  Mechanistic studies of the oxygen evolution reaction by a cobalt-phosphate catalyst at neutral pH. , 2010, Journal of the American Chemical Society.

[19]  Yoshio Nishi,et al.  Electronic correlation effects in reduced rutile TiO 2 within the LDA+U method , 2010 .

[20]  X. Lou,et al.  Shape-controlled synthesis of porous Co3O4 nanostructures for application in supercapacitors , 2010 .

[21]  Yiying Wu,et al.  NixCo3−xO4 Nanowire Arrays for Electrocatalytic Oxygen Evolution , 2010, Advanced materials.

[22]  A. Bell,et al.  Size-Dependent Activity of Co 3 O 4 Nanoparticle Anodes for Alkaline Water Electrolysis , 2009 .

[23]  Wenjie Shen,et al.  Low-temperature oxidation of CO catalysed by Co3O4 nanorods , 2009, Nature.

[24]  F. Schüth,et al.  Pseudomorphic transformation of highly ordered mesoporous Co3O4 to CoO via reduction with glycerol. , 2008, Journal of the American Chemical Society.

[25]  A. Walsh,et al.  Electronic, energetic, and chemical effects of intrinsic defects and Fe-doping of CoAl2O4: A DFT+U study , 2008 .

[26]  Shengbai Zhang,et al.  First-principles study of native defects in anatase Ti O 2 , 2006 .

[27]  David J. Singh,et al.  BoltzTraP. A code for calculating band-structure dependent quantities , 2006, Comput. Phys. Commun..

[28]  C. Walle,et al.  First-principles calculations for defects and impurities: Applications to III-nitrides , 2004 .

[29]  Burke,et al.  Generalized Gradient Approximation Made Simple. , 1996, Physical review letters.

[30]  Blöchl,et al.  Projector augmented-wave method. , 1994, Physical review. B, Condensed matter.

[31]  Hafner,et al.  Ab initio molecular-dynamics simulation of the liquid-metal-amorphous-semiconductor transition in germanium. , 1994, Physical review. B, Condensed matter.

[32]  Kuiper,et al.  Electronic structure of CoO, Li-doped CoO, and LiCoO2. , 1991, Physical review. B, Condensed matter.

[33]  Z. Ren,et al.  Efficient solar water-splitting using a nanocrystalline CoO photocatalyst. , 2014, Nature nanotechnology.

[34]  Abdullah M. Asiri,et al.  Mesoporous Co3O4 as an electrocatalyst for water oxidation , 2012, Nano Research.

[35]  Bing Tan,et al.  Mesoporous Co3O4 nanowire arrays for lithium ion batteries with high capacity and rate capability. , 2008, Nano letters.