Photoelectrocatalysis: principles, nanoemitter applications and routes to bio-inspired systems

Lewerenz, H. J.; Heine, Christian; Skorupska, Katarzyna; Szabó, N.; Hannappel, Thomas; Vo‐Dinh, Tuan; Campbell, S. A.; Klemm, Hagen W.; Muñoz, Ana

doi:10.1039/b915922n

Cited by 97 publications

(56 citation statements)

References 90 publications

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“…For p-type absorbers, conduction band alignment is not uncommon. 31 Indium oxides, for example, have electron affinities around 4.5eV, hence efficient excess minority transfer from most semiconductor conduction bands becomes possible. An example has been drawn in Fig.…”

Section: Carrier Transport Across Interphasesmentioning

confidence: 99%

“…The structure Rh/ interphase/p-InP (100):(2×4)/InP substrate was immersed into 1M HClO 4 and cycled for further optimization which resulted in a solarto-hydrogen efficiency of 14.5% if the efficiency determination from Ref. 47 is used 31 and of η = 12.4% if one takes the potential of the hydrogen redox couple as reference. The output characteristics are displayed in Fig.…”

Section: Case Studies: Surface Transformationsmentioning

confidence: 99%

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Semiconductor Surface Transformations for Photoelectrochemical Energy Conversion

Lewerenz¹

2014

J. Electrochem. Soc.

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The issue of photoelectrode stability, while simultaneously maintaining efficient operation in aqueous solutions, is addressed for energy converting half cells and complete photoelectrocatalytic structures. The historical development of stability concepts, their realization and recent advances are described. Examples are presented that span the time from the inception of photoelectrochemical energy conversion to present day's renewed interest in storable solar energy. The application of (photo)corrosion processes for in-situ synthesis of protective coatings is described and chemical and electronic analyses of the interphases formed are given. Future development and innovation routes will be discussed. The early days of light-induced processes at the solid-electrolyte interface were characterized by a series of fascinating effects. They encompass fundamental investigations of semiconductor-electrolyte junctions, 1,2 the first light-assisted water splitting, 3 photoemission from metals into solution, 4,5 hot electron processes 6,7 and the first carbon dioxide reduction at illuminated semiconductors. 8,9 The conceptual basis of energy conversion at the solid-liquid junction was provided by Gerischer in 1975 when the rectifying nature of the semiconductor-redox electrolyte contact was outlined.1 The elegance of formation of a conformal contact, simply by immersion of the samples into solution, was, however, neutralized by interfacial reactivity that gives rise to photocorrosion. 10,11 In the early assessment of stability of semiconductors at electrolyte junctions, thermodynamic decomposition potentials were introduced and their energy relation relative to the semiconductor band edges was analyzed.10,12 It soon turned out that stability is a predominant and major issue in photoelectrochemical energy conversion in both the photovoltaic and photoelectrocatalytic modes. Early development of stable photoelectrodes, based on the group VIb transition metal dichalcogenides, [13][14][15] which are also characterized by high absorptivity, was compromised by the problem of scalable preparation of efficient electrodes. Technologically advanced semiconductors from the III-V and II-VI groups typically showed rather high conversion efficiencies [16][17][18] but, also, often pronounced photocorrosion.19 A promising approach for stabilization was developed by the Bell Laboratories group where ∼ 10% efficient InP photocathodes had been operated for extended time in aqueous solution. 20The employed conditioning method resulted in the formation of interfacial films 21 that enabled electron transfer but that blocked access of solution components to the absorber surface thereby suppressing the corrosion reactions.In this text, fundamental aspects and recent developments and advances of this method will be outlined and discussed. Basic concepts on stability and photocorrosion are presented first, followed briefly by a discussion of carrier transport across interfacial films. A subsequent section describes the chronological development of ...

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Section: Carrier Transport Across Interphasesmentioning

confidence: 99%

Section: Case Studies: Surface Transformationsmentioning

confidence: 99%

Semiconductor Surface Transformations for Photoelectrochemical Energy Conversion

Lewerenz¹

2014

J. Electrochem. Soc.

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“…The individual steps of this sequence comprise of absorption by the semiconductor photocatalyst, composite materials or dyes. The excitation energy transfer from the absorber to the catalyst is usually assumed to be an electronic conduction process, which, in less ordered semiconducting materials could also be due to a hopping mechanism and dispersive transport of the light-induced excess electrons in the conduction band of semiconductor to its surface (Lewerenz et al 2010). These photoprocesses together with electric energy produce synergistic effect in the degradation of chemical compounds.…”

Section: Photoelectrocatalysismentioning

confidence: 99%

Perspectives and Advances in Photocatalysis

Gaya

2013

Heterogeneous Photocatalysis Using Inorganic Semiconductor Solids

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Interest in heterogeneous photocatalysis has heightened in the past 40 years, underscoring several perspectives and advances. A collection of applications including solar to fuel cells, intelligent ink and remote photocatalysis have been closely examined. As an emerging panacea for the treatment of recalcitrant pollutants, heterogeneous photocatalytic degradation has been highlighted with specific reference to synthetic aliphatic and aromatic organic substances. What's more, various treatment technologies for integration with photocatalytic degradation have been outlined.

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“…In recent work, high photocurrents were obtained on a Rh nanoparticle/oxide/InP structure for light-induced hydrogen evolution. [9] We presently investigate whether the surface plasmon resonance of Rh nanoparticles of about 3-5 nm radius and their spatial arrangement influences the absorption/reflectivity of the device. In principle, both, the resonant collective electron density variation of the surface mode and the enhanced electric field strength close to the interface to a dielectric such as water can influence the actual catalytic process and the optical behaviour.…”

Section: Introductionmentioning

confidence: 99%

Fundamental Aspects of Electrodeposition for the Realization of Plasmonic Nanostructures

Muñoz¹,

Skorupska²,

Lewerenz³

2010

ChemPhysChem

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Electrodeposition is used for the preparation of nanoparticles and nanostructures that allow, in principle, surface plasmon excitation. The (photo)electrodeposition process of Rh and Au nanoparticles as well as of heterodimeric enzymes onto silicon surfaces is investigated and the resulting structures are discussed with regard to applications in photoelectroctalysis and biosensing. Electrodeposition of Rh onto H-terminated p-Si surfaces generates nanostructures of the metal nanoparticles with simultaneous oxidation of the substrate thus forming nano-dimensioned metal-oxide-semiconductor (MOS)-type contacts. The excess minority carrier harvesting in these nanoemitter structures, where semispherical space charge layers underneath the metal exist are discussed based on spectral sensitivity and capacitance measurements The deposition of Au nanoparticles by a combined chemical-electrochemical method on Si is presented as an example for sensing actuators where the resonance frequency is changed by adsorption. Similarly, site-selective deposition of the enzyme reverse transcriptase onto nanostructured (step-bunched) silicon serves as precursor experiment for biosensing in a Kretschmann-type ATR configuration. Future applications based on plasmonically active structures are outlined.

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Photoelectrocatalysis: principles, nanoemitter applications and routes to bio-inspired systems

Cited by 97 publications

References 90 publications

Semiconductor Surface Transformations for Photoelectrochemical Energy Conversion

Semiconductor Surface Transformations for Photoelectrochemical Energy Conversion

Perspectives and Advances in Photocatalysis

Fundamental Aspects of Electrodeposition for the Realization of Plasmonic Nanostructures

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