Passivating surface states on water splitting hematite photoanodes with alumina overlayers

Hematite is a promising material for inexpensive solar energy conversion viawater splitting but has been limited by the large overpotential (0.5–0.6 V) that must be applied to afford high wateroxidation photocurrent. This has conventionally been addressed by coating it with a catalyst to increase the kinetics of the oxygen evolution reaction. However, surface recombination at trapping states is also thought to be an important factor for the overpotential, and herein we investigate a strategy to passivate trapping states using conformal overlayers applied by atomic layer deposition. While TiO2 overlayers show no beneficial effect, we find that an ultra-thin coating of Al2O3 reduces the overpotential required with state-of-the-art nano-structured photo-anodes by as much as 100 mV and increases the photocurrent by a factor of 3.5 (from 0.24 mA cm−2 to 0.85 mA cm−2) at +1.0 V vs. the reversible hydrogen electrode (RHE) under standard illumination conditions. The subsequent addition of Co2+ ions as a catalyst further decreases the overpotential and leads to a record photocurrent density at 0.9 V vs. RHE (0.42 mA cm−2). A detailed investigation into the effect of the Al2O3 overlayer by electrochemical impedance and photoluminescence spectroscopy reveals a significant change in the surface capacitance and radiative recombination, respectively, which distinguishes the observed overpotential reduction from a catalytic effect and confirms the passivation of surface states. Importantly, this work clearly demonstrates that two distinct loss processes are occurring on the surface of high-performance hematite and suggests a viable route to individually address them.

[1]  Jianwei Sun,et al.  Solar water oxidation by composite catalyst/alpha-Fe(2)O(3) photoanodes. , 2009, Journal of the American Chemical Society.

[2]  Han-Bo-Ram Lee,et al.  Applications of atomic layer deposition to nanofabrication and emerging nanodevices , 2009 .

[3]  M. Grätzel,et al.  Decoupling feature size and functionality in solution-processed, porous hematite electrodes for solar water splitting. , 2010, Nano letters.

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

[5]  Vladimir M. Aroutiounian,et al.  Investigations of the Fe1.99Ti0.01O3–electrolyte interface , 2000 .

[6]  Jun-Ho Yum,et al.  Examining architectures of photoanode–photovoltaic tandem cells for solar water splitting , 2010 .

[7]  Tunnel barrier photoelectrodes for solar water splitting , 2010 .

[8]  Tina C. Li,et al.  Surface passivation of nanoporous TiO 2 via atomic layer deposition of ZrO 2 for solid-state dye-sensitized solar cell applications , 2009 .

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

[10]  John H. Kennedy,et al.  Flatband Potentials and Donor Densities of Polycrystalline α ‐ Fe2 O 3 Determined from Mott‐Schottky Plots , 1978 .

[11]  Michael Grätzel,et al.  Light-induced water splitting with hematite: improved nanostructure and iridium oxide catalysis. , 2010, Angewandte Chemie.

[12]  David M. Sherman,et al.  Electronic spectra of Fe3+ oxides and oxide hydroxides in the near IR to near UV , 1985 .

[13]  J. Leduc,et al.  Photoelectrochemical and impedance characteristics of specular hematite. 2. Deep bulk traps in specular hematite at small a.c. frequencies , 1988 .

[14]  F. Freund,et al.  Formation of O− Centers by Homolytic Decomposition of OH− Groups on Magnesium Oxide , 1975 .

[15]  Michael Grätzel,et al.  WO3-Fe2O3 Photoanodes for Water Splitting: A Host Scaffold, Guest Absorber Approach , 2009 .

[16]  M. Grätzel,et al.  Controlling Photoactivity in Ultrathin Hematite Films for Solar Water‐Splitting , 2010 .

[17]  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.

[18]  V. Volkov,et al.  Surface modification on time-resolved fluorescences of Fe2O3 nanocrystals , 2000 .

[19]  G. Horowitz Capacitance-voltage measurements and flat-band potential determination on Zr-doped α-Fe2O3 single-crystal electrodes , 1983 .

[20]  Michael Grätzel,et al.  Influence of Feature Size, Film Thickness, and Silicon Doping on the Performance of Nanostructured Hematite Photoanodes for Solar Water Splitting , 2009 .

[21]  R. Grimes,et al.  Accommodation of impurities in α-Al2O3, α-Cr2O3 and α-Fe2O3 , 2003 .

[22]  M. Dupuis,et al.  An ab initio model of electron transport in hematite (α-Fe2O3) basal planes , 2003 .

[23]  M. Misra,et al.  Water Photooxidation by Smooth and Ultrathin α-Fe2O3 Nanotube Arrays , 2009 .

[24]  N. S. Mcalpine,et al.  Characterization of Ti-doped α-Fe2O3, electrodes by impedance measurements , 1988 .

[25]  Craig A. Grimes,et al.  Synthesis and photoelectrochemical properties of nanoporous iron (III) oxide by potentiostatic anodization , 2006 .

[26]  G. Somorjai,et al.  The photoelectrochemistry of niobium doped α-Fe2O3 , 1988 .

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

[28]  G. M. Stepanyan,et al.  Investigations of the structure of the iron oxide semiconductor–electrolyte interface , 2006 .

[29]  P. Iwanski,et al.  The Photoelectrochemical Behavior of Ferric Oxide in the Presence of Redox Reagents , 1981 .

[30]  John B. Goodenough,et al.  Electrochemistry and photoelectrochemistry of iron(III) oxide , 1983 .

[31]  R. Hausbrand,et al.  Electronic properties of thermally formed thin iron oxide films , 2007 .

[32]  S. M. Ahmed,et al.  Photoelectrochemical and impedance characteristics of specular hematite. 1. Photoelectrochemical parallel conductance, and trap rate studies , 1988 .

[33]  Liang Li,et al.  Core/Shell semiconductor nanocrystals. , 2009, Small.

[34]  M. Grätzel Photoelectrochemical cells : Materials for clean energy , 2001 .

[35]  A. Hagfeldt,et al.  Photoelectrochemical Studies of Oriented Nanorod Thin Films of Hematite , 2000 .

[36]  E. McFarland,et al.  Improved photoelectrochemical performance of Ti-doped alpha-Fe2O3 thin films by surface modification with fluoride. , 2009, Chemical communications.