Photoelectrochemical Conditioning of MOVPE p-InP Films for Light-Induced Hydrogen Evolution: Chemical, Electronic and Optical Properties

Muñoz, Ana; Heine, Christian; Lublow, Michael; Klemm, Hagen W.; Szabó, N.; Hannappel, Thomas; Lewerenz, H. J.

doi:10.1149/2.016304jss

Cited by 31 publications

(39 citation statements)

References 52 publications

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“…While AlInP exhibits χ =3.8 eV (ref. 18), it changes to χ ≈4.4 eV for indium oxide31. Such differences in electron affinity between III–V semiconductors and their oxides with their potential impact on the photovoltage have already been addressed in the literature37.…”

Section: Discussionmentioning

confidence: 87%

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

et al. 2015

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Photosynthesis is nature's route to convert intermittent solar irradiation into storable energy, while its use for an industrial energy supply is impaired by low efficiency. Artificial photosynthesis provides a promising alternative for efficient robust carbon-neutral renewable energy generation. The approach of direct hydrogen generation by photoelectrochemical water splitting utilizes customized tandem absorber structures to mimic the Z-scheme of natural photosynthesis. Here a combined chemical surface transformation of a tandem structure and catalyst deposition at ambient temperature yields photocurrents approaching the theoretical limit of the absorber and results in a solar-to-hydrogen efficiency of 14%. The potentiostatically assisted photoelectrode efficiency is 17%. Present benchmarks for integrated systems are clearly exceeded. Details of the in situ interface transformation, the electronic improvement and chemical passivation are presented. The surface functionalization procedure is widely applicable and can be precisely controlled, allowing further developments of high-efficiency robust hydrogen generators.

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Section: Discussionmentioning

confidence: 87%

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

et al. 2015

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“…The stability at pH14, however, is limited (about 2 h). In comparison to the most effi cient devices for photoassisted evolution of hydrogen published so far, planar Si-Pt and InP-Rh heterojunctions [ 25,26 ] with effi ciencies of 9.6% and 14.5%, respectively, the TiO 2 :Pt-Cu(In,Ga)Se 2 system shows higher saturation photocurrent densities but operates less active. However, our CIGSe substrates are characterized by uniform doping while both the Si and InP absorbers were fabricated as homojunctions with a highly doped surface-near region, improving thereby considerably the achievable photovoltage.…”

Section: Wileyonlinelibrarycommentioning

confidence: 97%

Efficient and Stable TiO₂:Pt–Cu(In,Ga)Se₂ Composite Photoelectrodes for Visible Light Driven Hydrogen Evolution

Azarpira

Lublow

Steigert

et al. 2015

Advanced Energy Materials

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Novel thin film composite photocathodes based on device‐grade Cu(In,Ga)Se2 chalcopyrite thin film absorbers and transparent conductive oxide Pt‐implemented TiO2 layers on top are presented for an efficient and stable solar‐driven hydrogen evolution. Thin films of phase‐pure anatase TiO2 are implemented with varying Pt‐concentrations in order to optimize simultaneously i) conductivity of the films, ii) electrocatalytic activity, and iii) light‐guidance toward the chalcopyrite. Thereby, high incident‐photon‐to‐current‐efficiencies of more than 80% can be achieved over the full visible light range. In acidic electrolyte (pH 0.3), the most efficient Pt‐implemented TiO2–Cu(In,Ga)Se2 composite electrodes reveal i) photocurrent densities up to 38 mA cm−2 in the saturation region (−0.4 V RHE, reversible hydrogen electrode), ii) 15 mA cm−2 at the thermodynamic potential for H2‐evolution (0 V RHE), and iii) an anodic onset potential shift for the hydrogen evolution (+0.23 V RHE). It is shown that the gradual increase of the Pt‐concentration within the TiO2 layers passes through an efficiency‐ and stability‐maximum of the device (5 vol% of Pt precursor solution). At this maximum, optimized light‐incoupling into the device‐grade chalcopyrite light‐absorber as well as electron conductance properties within the surface layer are achieved while no degradation are observed over more than 24 h of operation.

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“…3(a). 12 The photodiode is a heterojunction of p-InP and n-InO x P y , where the photoactive layer is p-type InP and the voltage is maximized by the use of a thin, highly doped layer of n-InO x P y . Figure 3(b) compares the modeled and experimental current density versus voltage behavior.…”

Section: Current-voltage Characteristics Of Coupled Photodiode-electrmentioning

confidence: 99%

Current-voltage characteristics of coupled photodiode-electrocatalyst devices

Shaner

Fountaine

Lewerenz

2013

Applied Physics Letters

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Analytical expressions for the illuminated current-voltage characteristics of coupled photodiode-electrocatalyst fuel forming devices are derived. The approach is based on combining solid-state diode behavior with metal electrochemistry via the diode equation and the Butler-Volmer equation (charge transfer coefficients: αA = αC = α) or the Tafel equation (|η|≥118mVne), respectively. The analytical expression for the current-voltage behavior of the coupled photodiode-electrocatalyst device (αA = αC = 0.5) and an isolated photodiode is plotted, compared, and augmented with band diagrams at equilibrium, open circuit, short circuit, and the maximum power point to illustrate the effect of coupling an electrocatalyst to a photodiode. The applicability of the derived equations is then demonstrated by comparing with a recently reported high efficiency, thin film InP/InOxPy/Rh photoelectrosynthetic hydrogen evolution device.

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Photoelectrochemical Conditioning of MOVPE p-InP Films for Light-Induced Hydrogen Evolution: Chemical, Electronic and Optical Properties

Cited by 31 publications

References 52 publications

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

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

Efficient and Stable TiO₂:Pt–Cu(In,Ga)Se₂ Composite Photoelectrodes for Visible Light Driven Hydrogen Evolution

Current-voltage characteristics of coupled photodiode-electrocatalyst devices

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Photoelectrochemical Conditioning of MOVPE p-InP Films for Light-Induced Hydrogen Evolution: Chemical, Electronic and Optical Properties

Cited by 31 publications

References 52 publications

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

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

Efficient and Stable TiO2:Pt–Cu(In,Ga)Se2 Composite Photoelectrodes for Visible Light Driven Hydrogen Evolution

Current-voltage characteristics of coupled photodiode-electrocatalyst devices

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Efficient and Stable TiO₂:Pt–Cu(In,Ga)Se₂ Composite Photoelectrodes for Visible Light Driven Hydrogen Evolution