Sputtered NiOx films for stabilization of p+ n-InP photoanodes for solar-driven water oxidation
A reactively sputtered NiOx film has been used here to stabilize a buried-junction p+ n-InP
photoanode from anodic dissolution/corrosion for> 48 h of continuous light-driven evolution …
photoanode from anodic dissolution/corrosion for> 48 h of continuous light-driven evolution …
Ultrafast Electron Dynamics at the P‐rich Indium Phosphide/TiO2 Interface
J Diederich, JV Rojas, A Paszuk… - Advanced Functional …, 2024 - Wiley Online Library
The current efficiency records for generating green hydrogen via solar water splitting are
held by indium phosphide (InP)‐based photo‐absorbers, protected by TiO2 layers grown …
held by indium phosphide (InP)‐based photo‐absorbers, protected by TiO2 layers grown …
Unraveling Electron Dynamics in p-type Indium Phosphide (100): A Time-Resolved Two-Photon Photoemission Study
J Diederich, J Velasquez Rojas… - Journal of the …, 2024 - ACS Publications
Renewable (“green”) hydrogen production through direct photoelectrochemical (PEC) water
splitting is a potential key contributor to the sustainable energy mix of the future. We …
splitting is a potential key contributor to the sustainable energy mix of the future. We …
Epitaxial III–V films and surfaces for photoelectrocatalysis
Efficient photoelectrochemical devices for water splitting benefit from the highest material
quality and dedicated surface preparation achieved by epitaxial growth. InP (100)‐based …
quality and dedicated surface preparation achieved by epitaxial growth. InP (100)‐based …
The interfacial structure of InP (100) in contact with HCl and H 2 SO 4 studied by reflection anisotropy spectroscopy
M Löw, M Guidat, J Kim, MM May - RSC advances, 2022 - pubs.rsc.org
Indium phosphide and derived compound semiconductors are materials often involved in
high-efficiency solar water splitting due to their versatile opto-electronic properties. Surface …
high-efficiency solar water splitting due to their versatile opto-electronic properties. Surface …
On the origin of the photocurrent of electrochemically passivated p-InP (100) photoelectrodes
III–V semiconductors such as InP are highly efficient light absorbers for
photoelectrochemical (PEC) water splitting devices. Yet, their cathodic stability is limited due …
photoelectrochemical (PEC) water splitting devices. Yet, their cathodic stability is limited due …
Modulation of surface bonding topology: Oxygen bridges on OH-terminated InP (001)
An understanding and control of complex physiochemical processes at the photoelectrode/
electrolyte interface in photoelectrochemical cells (PECs) are essential for develo** …
electrolyte interface in photoelectrochemical cells (PECs) are essential for develo** …
Micro-and nanotopographies for photoelectrochemical energy conversion. II: Photoelectrocatalysis–Classical and advanced systems
HJ Lewerenz, K Skorupska, AG Muñoz, T Stempel… - Electrochimica …, 2011 - Elsevier
The present trends on water photolysis are shortly reviewed. For application in
monolithically integrated structures, photoelectrocatalytically active half cell developments …
monolithically integrated structures, photoelectrocatalytically active half cell developments …
Epitaxial III-V Thin Film Absorbers: Preparation, Efficient InP Photocathodes and Routes to High Efficiency Tandem Structures
T Hannappel, MM May, HJ Lewerenz - 2013 - books.rsc.org
Photovoltaic solar energy conversion and photoelectrochemical water splitting differ due to
the variability of the output power in photovoltaics, whereas lightinduced water dissociation …
the variability of the output power in photovoltaics, whereas lightinduced water dissociation …
[PDF][PDF] Ultrafast Electron Dynamics at the P-rich Indium Phosphide/TiO
J Diederich, JV Rojas, A Paszuk, MAZ Pour, C Höhn… - 2024 - d-nb.info
The current efficiency records for generating green hydrogen via solar water splitting are
held by indium phosphide (InP)-based photo-absorbers, protected by TiO2 layers grown …
held by indium phosphide (InP)-based photo-absorbers, protected by TiO2 layers grown …