Efficient direct solar-to-hydrogen conversion by in situ interface transformation of a tandem structure

May, Matthias M.; Lewerenz, H. J.; David, Laurent; Dimroth, Frank; Hannappel, Thomas

doi:10.1038/ncomms9286

Cited by 265 publications

(278 citation statements)

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“…[7][8][9] However, the cost of these photoelectrodes is likely to be prohibitive, and most of them suffer from instability in aqueous solutions. In contrast, metal oxide semiconductors are relatively cheap and stable in aqueous solutions, but photoelectrodes based on metal oxides have only shown moderate efficiencies (< 8%).…”

Section: Introductionmentioning

confidence: 99%

Enhancing Charge Carrier Lifetime in Metal Oxide Photoelectrodes through Mild Hydrogen Treatment

Jang

Friedrich

Müller

et al. 2017

Advanced Energy Materials

115

164

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Widespread application of solar water splitting for energy conversion is largely dependent on the progress in developing not only efficient, but also cheap and scalable photoelectrodes. Metal oxides, which can be deposited with scalable techniques and are relatively cheap, are particularly interesting, but high efficiency is still hindered by the poor carrier transport properties (i.e., carrier mobility and lifetime). In this paper, a mild hydrogen treatment is introduced to bismuth vanadate (BiVO4), which is one of the most promising metal oxide photoelectrodes, as a method to overcome the carrier transport limitations. Timeresolved microwave and terahertz conductivity measurements reveal more than two-fold enhancement of the carrier lifetime for the hydrogen-treated BiVO4, without significantly affecting the carrier mobility. This is in contrast to the case of tungsten-doped BiVO4, although hydrogen is also shown to be a donor type dopant in BiVO4. The enhancement in carrier lifetime is found to be caused by significant reduction of trap-assisted recombination, either via passivation of deep trap states or reduction of trap state density, which can be related to vanadium anti-site on bismuth or vanadium interstitials according to density functional theory calculations. Overall, these findings provide further insights on the interplay between defect modulation and carrier transport in metal oxide photoelectrodes, which will benefit the development of low-cost, highly-efficient solar energy conversion devices.

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Section: Introductionmentioning

confidence: 99%

Enhancing Charge Carrier Lifetime in Metal Oxide Photoelectrodes through Mild Hydrogen Treatment

Jang

Friedrich

Müller

et al. 2017

Advanced Energy Materials

115

164

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“…Although the active areas are typically small, <0.5 cm 2 , impressive efficiencies (up to 14%) and lifetimes of up to several days have been reached. 3,27 These devices are still in an early stage of development and so, it is yet unknown whether they can provide Figure 2. Left: Schematic drawing of the system showing the concept for solar collection and conversion to electricity and stored heat.…”

Section: Research Needs For Photoelectrochemical Fuel Productionmentioning

confidence: 99%

“…One example is a 64 cm 2 modular demonstrator based on triple-junction silicon cells with an efficiency of 3.9% and a lifetime of more than 40 h. 2 PV-driven devices based on III-V semiconductors show higher efficiencies but are more expensive and do not have a scalable design. 3 At the other end of the spectrum are oxide-based devices, which can be cheap but show poor efficiencies. 4 Further development of these preprototype systems is needed as a precursor to the required industrial level scale-up to enable solar fuels to have a real impact.…”

Section: Introductionmentioning

confidence: 99%

Perspectives on the photoelectrochemical storage of solar energy

Krol

Parkinson

2017

MRS Energy & Sustainability

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Direct photoelectrochemical water splitting offers several advantages over PV-powered electrolysis and may become the technology of choice in the future. However, significant R&D efforts and breakthroughs are needed to accomplish this goal.The sustainable production of hydrogen would be an important first step for both powering fuel cells and for enabling large-scale and technologically mature gas phase processes to reduce CO 2 and nitrogen to get desired products. Specifically, the central challenge is to produce hydrogen from water using sunlight. Photovoltaics and wind-powered electrolysis are likely to be the technology of choice to produce renewable hydrogen for the next few decades. However, the integration of light absorption and catalysis in 'direct' photoelectrolysis routes offers several advantages, such as lower current densities and better heat management, and may become technologically relevant in the second half of this century. This article discusses the research and development efforts and needed breakthroughs to achieve this goal. New chemically stable semiconductors with a band gap between 1.5 and 2.0 eV and long carrier lifetimes are urgently needed to make efficient tandem devices.Scale-up of these research level devices beyond a few cm 2 introduces mass transport limitations that require creative electrochemical engineering solutions. Last but not least, standardized methods for measuring efficiencies and stabilities need to be implemented and should lead to official benchmarking and certification laboratories to guide commercial scale up efforts. Keywords: photochemical; energy storage; energy generation RevIew DISCUSSION POINTS• Water splitting will be a central challenge for any future fossil fuel-free energy infrastructure that relies on liquid or gaseous chemical fuels.• While the main materials challenge for solar-and wind-driven electrolysis is the development of better catalysts, the main challenge for photoelectrochemical water splitting is to find new chemically stable optimal-bandgap semiconducting light absorbers.• Further progress in the development of photo-driven water splitting generators requires significant additional efforts in electrochemical engineering and the development of standardized methods for benchmarking device performance and stability.

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“…The innovation by Fujishima and Honda Laboratories produced the first viable PEC water-splitting cell with an approximate quantum efficiency of 0.1%. To date, solar-to-H 2 (STH) efficiencies of 12.7% have been achieved using a p-GaInP 2 /GaAs electrode as photoanode [6], and the record has only recently been surpassed at 14% using a Z-scheme tandem cell comprised of Rh-functionalized AlInPO x photocathode and RuO 2 as photoanode [7].…”

Section: Introductionmentioning

confidence: 99%

Photocatalytic Water Oxidation on ZnO: A Review

2017

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Abstract:The investigation of the water oxidation mechanism on photocatalytic semiconductor surfaces has gained much attention for its potential to unlock the technological limitations of producing H 2 from carbon-free sources, i.e., H 2 O. This review seeks to highlight the available scientific and fundamental understanding towards the water oxidation mechanism on ZnO surfaces, as well as present a summary on the modification strategies carried out to increase the photocatalytic response of ZnO.

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Efficient direct solar-to-hydrogen conversion by in situ interface transformation of a tandem structure

Cited by 265 publications

References 50 publications

Enhancing Charge Carrier Lifetime in Metal Oxide Photoelectrodes through Mild Hydrogen Treatment

Enhancing Charge Carrier Lifetime in Metal Oxide Photoelectrodes through Mild Hydrogen Treatment

Perspectives on the photoelectrochemical storage of solar energy

Photocatalytic Water Oxidation on ZnO: A Review

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