Passivating surface states on water splitting hematite photoanodes with alumina overlayers

Formal, Florian Le; Tétreault, Nicolas; Cornuz, Maurin; Moehl, Thomas; Grätzel, Michaël; Sivula, Kevin

doi:10.1039/c0sc00578a

Cited by 770 publications

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“…Similar looking impedance spectra have recently been reported for hematite electrodes, and a variety of equivalent circuits put forth interpret these spectra. 11,45 In these analyses, the low frequency semicircle is generally attributed to the series arrangement of the depletion capacitance of the semiconductor SC C and the Helmholtz capacitance at the electrode surface, and the role of surface states has largely been ignored.…”

Section: Resultsmentioning

confidence: 99%

Water Oxidation at Hematite Photoelectrodes: The Role of Surface States

et al. 2012

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Published asKlahrHowever, 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. 3 I ntroductionAs part of the quest to develop better and cleaner energy conversion and storage systems, the direct conversion of sunlight into chemical fuels has become a subject of renewed interest.One attractive example is the use of semiconductors to harness solar photons to split water, thereby producing hydrogen as a chemical fuel. In order to achieve this, a given material must satisfy a number of stringent requirements including visible light absorption, efficient charge carrier separation and transport, facile interfacial charge-transfer kinetics, appropriate positions of the conduction and valence band energy levels with respect to required reaction potentials and good stability in contact with aqueous solutions. 1 While such systems were heavily investigated several decades ago, no material so far has fulfilled all the required conditions. 2,3 Recent advances in nanotechnology and catalysis, however, greatly increase the prospects of developing a combination of materials capable of efficient conversion of sunlight to chemical fuels. 4 Hematite ( -Fe 2 O 3 ) is a very promising material for photoelectrochemical (PEC) water splitting due to its combination of sufficiently broad visible light absorption, up to 590 nm, and excellent stability under caustic operating conditions. 5,6 However, hematite electrodes are adversely affected by a number of factors including a long penetration depth of visible light due to its indirect band gap transition and a very short minority carrier lifetime and mobility; this combination hinders efficient collection of the minority carriers via the required interfacial charge-transfer reactions. Considerable effort has been devoted to improving the actual efficiency by employing nanostructuring strategies, which disconnects the ligh...

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Section: Resultsmentioning

confidence: 99%

Water Oxidation at Hematite Photoelectrodes: The Role of Surface States

et al. 2012

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“…For example, reaction of silicon with HF can suppress surface recombination and improve the performance of photovoltaic devices [138]. For Fe 2 O 3 photoanodes it has been shown that application of Al 2 O 3 [151] or SnO 2 [152] overlayers also improves the performance. For BiVO 4 photoanodes, both application of an SnO 2 underlayer [153], and incorporation of W dopants boost the electrical power output, which is attributed to reduction of surface recombination Fig.…”

Section: Electron-hole Recombinationmentioning

confidence: 99%

Nanoscale Effects in Water Splitting Photocatalysis

Osterloh

2015

Topics in Current Chemistry

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From a conceptual standpoint, the water photoelectrolysis reaction is the simplest way to convert solar energy into fuel. It is widely believed that nanostructured photocatalysts can improve the efficiency of the process and lower the costs. Indeed, nanostructured light absorbers have several advantages over traditional materials. This includes shorter charge transport pathways and larger redox active surface areas. It is also possible to adjust the energetics of small particles via the quantum size effect or with adsorbed ions. At the same time, nanostructured absorbers have significant disadvantages over conventional ones. The larger surface area promotes defect recombination and reduces the photovoltage that can be drawn from the absorber. The smaller size of the particles also makes electron-hole separation more difficult to achieve. This chapter discusses these issues using selected examples from the literature and from the laboratory of the author.

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“…Illumination on hematite induces the accumulation of photogenerated charges at the interfaces, in particular, hole congregation at the semiconductorelectrolyte junction due to the low mobilities for the charge carriers and the slow kinetics of the oxygen generation reaction. 21,22 Small transient response with our bare hematite may be due to dense nature of film with low surface area. For the Co-Pi/hematite sample (Figure 3), an anodic current spike is also observed during this charge accumulation phase, which decreases rapidly with time and forward potential sweep because the accumulated holes disorder the charge dissemination in the space charge layer.…”

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confidence: 93%

“…The current linearly increases with increasing potential up to ~1.35 V and begins to decline before sharply increasing at 1.65 V vs. RHE, consistent with the behavior reported for hematite photoanodes. 21 On the Co-Pi/hematite, the photocurrent onset occurs at ~ 0.8 V vs. RHE. In addition, the current increases along with a positive sweep and begins to decline once a higher potential regime is reached (Figure 3a).…”

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confidence: 99%