Water oxidation at hematite photoelectrodes: the role of surface states.

Hematite (α-Fe(2)O(3)) constitutes one of the most promising semiconductor materials for the conversion of sunlight into chemical fuels by water splitting. Its inherent drawbacks related to the long penetration depth of light and poor charge carrier conductivity are being progressively overcome by employing nanostructuring strategies and improved catalysts. However, the physical-chemical mechanisms responsible for the photoelectrochemical performance of this material (J(V) response) are still poorly understood. In the present study we prepared thin film hematite electrodes by atomic layer deposition to study the photoelectrochemical properties of this material under water-splitting conditions. We employed impedance spectroscopy to determine the main steps involved in photocurrent production at different conditions of voltage, light intensity, and electrolyte pH. A general physical model is proposed, which includes the existence of a surface state at the semiconductor/liquid interface where holes accumulate. The strong correlation between the charging of this state with the charge transfer resistance and the photocurrent onset provides new evidence of the accumulation of holes in surface states at the semiconductor/electrolyte interface, which are responsible for water oxidation. The charging of this surface state under illumination is also related to the shift of the measured flat-band potential. These findings demonstrate the utility of impedance spectroscopy in investigations of hematite electrodes to provide key parameters of photoelectrodes with a relatively simple measurement.

[1]  S. George Atomic layer deposition: an overview. , 2010, Chemical reviews.

[2]  Z. Hens The Electrochemical Impedance of One-Equivalent Electrode Processes at Dark Semiconductor|Redox Electrodes Involving Charge Transfer through Surface States. 1. Theory , 1999 .

[3]  P. Salvador Semiconductors' Photoelectrochemistry: A Kinetic and Thermodynamic Analysis in the Light of Equilibrium and Nonequilibrium Models , 2001 .

[4]  P. Salvador,et al.  Surface chemistry and interfacial charge-transfer mechanisms in photoinduced oxygen exchange at O2-TiO2 interfaces. , 2011, Chemphyschem : a European journal of chemical physics and physical chemistry.

[5]  F. Fabregat‐Santiago,et al.  Characterization of nanostructured hybrid and organic solar cells by impedance spectroscopy. , 2011, Physical chemistry chemical physics : PCCP.

[6]  C. Cao,et al.  Investigation of the kinetics of a TiO2 photoelectrocatalytic reaction involving charge transfer and recombination through surface states by electrochemical impedance spectroscopy. , 2005, The journal of physical chemistry. B.

[7]  G. Horowitz,et al.  Crystal growth and photoelectrochemical study of Zr-doped α-Fe2O3 single crystal☆ , 1982 .

[8]  Wolfgang W. Gärtner,et al.  Depletion-Layer Photoeffects in Semiconductors , 1959 .

[9]  P. Allongue,et al.  Band-edge shift and surface charges at illuminated n-GaAs/aqueous electrolyte junctions: surface-state analysis and simulation of their occupation rate , 1985 .

[10]  J. Kennedy,et al.  Photooxidation of Water at α ‐ Fe2 O 3 Electrodes , 1978 .

[11]  Alex B. F. Martinson,et al.  Atomic layer deposition of TiO2 on aerogel templates: New photoanodes for dye-sensitized solar cells , 2008 .

[12]  Anke Weidenkaff,et al.  Photoelectrochemical water splitting with mesoporous hematite prepared by a solution-based colloidal approach. , 2010, Journal of the American Chemical Society.

[13]  Yongjing Lin,et al.  Nanonet-based hematite heteronanostructures for efficient solar water splitting. , 2011, Journal of the American Chemical Society.

[14]  E. A. Ponomarev,et al.  A comparison of intensity modulated photocurrent spectroscopy and photoelectrochemical impedance spectroscopy in a study of photoelectrochemical hydrogen evolution at p-InP , 1995 .

[15]  Juan Bisquert,et al.  Chemical capacitance of nanostructured semiconductors: its origin and significance for nanocomposite solar cells , 2003 .

[16]  P. Searson,et al.  Analysis of the impedance response due to surface states at the semiconductor/solution interface , 1998 .

[17]  J. Kelly,et al.  The Influence of Surface Recombination and Trapping on the Cathodic Photocurrent at p‐Type III‐V Electrodes , 1982 .

[18]  Thomas W. Hamann,et al.  Photoelectrochemical investigation of ultrathin film iron oxide solar cells prepared by atomic layer deposition. , 2011, Langmuir : the ACS journal of surfaces and colloids.

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

[20]  Thomas W. Hamann,et al.  Control of the stability, electron-transfer kinetics, and pH-dependent energetics of Si/H2O interfaces through methyl termination of Si(111) surfaces. , 2006, The journal of physical chemistry. B.

[21]  J. Reichman The current‐voltage characteristics of semiconductor‐electrolyte junction photovoltaic cells , 1980 .

[22]  J. Hupp,et al.  Atomic Layer Deposition of Fe2O3 Using Ferrocene and Ozone , 2011 .

[23]  P. Salvador Influence of pH on the Potential Dependence of the Efficiency of Water Photo‐oxidation at n ‐ TiO2 Electrodes , 1981 .

[24]  J. Simmons,et al.  Nonequilibrium Steady-State Statistics and Associated Effects for Insulators and Semiconductors Containing an Arbitrary Distribution of Traps , 1971 .

[25]  Alexander J. Cowan,et al.  Dynamics of photogenerated holes in nanocrystalline α-Fe2O3 electrodes for water oxidation probed by transient absorption spectroscopy. , 2011, Chemical communications.

[26]  D. Klug,et al.  Mechanism of photocatalytic water splitting in TiO2. Reaction of water with photoholes, importance of charge carrier dynamics, and evidence for four-hole chemistry. , 2008, Journal of the American Chemical Society.

[27]  I. E. Grey,et al.  Efficiency of solar water splitting using semiconductor electrodes , 2006 .

[28]  S. Morrison Electrochemistry at Semiconductor and Oxidized Metal Electrodes , 1980 .

[29]  F. Cardon,et al.  A Quantitative Analysis of Photoinduced Capacitance Peaks in the Impedance of the n ‐ GaAs Electrode , 1987 .

[30]  V. Lazarescu,et al.  Surface states- and field-effects at p- and n-doped GaAs(111)A/solution interface. , 2009, Physical chemistry chemical physics : PCCP.

[31]  D. Ginley,et al.  Principles of photoelectrochemical, solar energy conversion , 1980 .

[32]  D. W. Tanner,et al.  The electrical properties of alpha ferric oxide—II.: Ferric oxide of high purity , 1963 .

[33]  Piers R. F. Barnes,et al.  Enhancement of Photoelectrochemical Hydrogen Production from Hematite Thin Films by the Introduction of Ti and Si , 2007 .

[34]  Juan Bisquert,et al.  Physical electrochemistry of nanostructured devices. , 2008, Physical chemistry chemical physics : PCCP.

[35]  S. Morrison,et al.  Electrochemical Measurements of Interface States at the GaAs / Oxide Interface , 1979 .

[36]  Philip J. Martin,et al.  Structural, optical and electrical properties of undoped polycrystalline hematite thin films produced using filtered arc deposition , 2008 .

[37]  Thomas W. Hamann,et al.  Aerogel Templated ZnO Dye‐Sensitized Solar Cells , 2008 .

[38]  Juan Bisquert,et al.  Interpretation of the Time Constants Measured by Kinetic Techniques in Nanostructured Semiconductor Electrodes and Dye-Sensitized Solar Cells , 2004 .

[39]  D. Klug,et al.  The role of cobalt phosphate in enhancing the photocatalytic activity of α-Fe2O3 toward water oxidation. , 2011, Journal of the American Chemical Society.

[40]  Juan Bisquert,et al.  A review of recent results on electrochemical determination of the density of electronic states of nanostructured metal-oxide semiconductors and organic hole conductors , 2008 .

[41]  Thomas W. Hamann,et al.  Current and Voltage Limiting Processes in Thin Film Hematite Electrodes , 2011 .

[42]  Michael Grätzel,et al.  Passivating surface states on water splitting hematite photoanodes with alumina overlayers , 2011 .

[43]  J. Bisquert,et al.  Fermi Level of Surface States in TiO2 Nanoparticles , 2003 .

[44]  L. Peter,et al.  Kinetics of oxygen evolution at α-Fe2O3 photoanodes: a study by photoelectrochemical impedance spectroscopy. , 2011, Physical chemistry chemical physics : PCCP.

[45]  F. Cardon,et al.  Calculation of the electrical impedance associated with the surface recombination of free carriers at an illuminated semiconductor/electrolyte interface , 1986 .

[46]  D. Lincot,et al.  Recombination and charge transfer at the illuminated n-CdTe/electrolyte interface. Simplified kinetic model , 1987 .

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

[48]  J. Elam,et al.  Indium Oxide Atomic Layer Deposition Facilitated by the Synergy between Oxygen and Water , 2011 .

[49]  J. Bisquert Theory of the impedance of charge transfer via surface states in dye-sensitized solar cells , 2010 .

[50]  Michael Grätzel,et al.  New Benchmark for Water Photooxidation by Nanostructured α-Fe2O3 Films , 2006 .