Add to ORKGEfficient light stimulated hydrogen generation from top down produced highly doped n type silicon nanowires SiNWs with silver nanoparticles AgNPs in water containing medium under white light irradiation is reported. It is observed that SiNWs with AgNPs generate at least 2.5 times more hydrogen than SiNWs without AgNPs. The authors results, based on vibrational, UV vis, and X ray spectroscopy studies, strongly suggest that the sidewalls of the SiNWs are covered by silicon suboxides, by up to a thickness of 120 nm, with wide bandgap semiconductor properties that are similar to those of titanium dioxide and remain stable during hydrogen evolution in a water containing medium for at least 3 h of irradiation. Based on synchrotron studies, i...
In this paper, we report that amorphous silicon oxide nanowires can be grown in a large quantity by ...
This thesis presents the development of Silicon-based nanomaterials for use as the functional compon...
We demonstrate that nanosize silicon (∼10 nm diameter) reacts with water to generate hydrogen 1000 t...
Efficient light stimulated hydrogen generation from top down produced highly doped n type silicon na...
Efficient light stimulated hydrogen generation from top down produced highly doped n type silicon na...
The origin of the photocurrent enhancement and the overpotential reduction in solar water splitting ...
The origin of the photocurrent enhancement and the overpotential reduction in solar water splitting ...
The performance of silicon for water oxidation and hydrogen production can be improved by exploiting...
The performance of silicon for water oxidation and hydrogen production can be improved by exploiting...
International audiencePhotoelectrochemical water splitting is a sustainable and environmentally frie...
International audiencePhotoelectrochemical water splitting is a sustainable and environmentally frie...
International audiencePhotoelectrochemical water splitting is a sustainable and environmentally frie...
International audiencePhotoelectrochemical water splitting is a sustainable and environmentally frie...
International audiencePhotoelectrochemical water splitting is a sustainable and environmentally frie...
Tungsten sulfides, including WS<sub>2</sub> (crystalline) and WS<sub>3</sub> (amorphous), were intro...
In this paper, we report that amorphous silicon oxide nanowires can be grown in a large quantity by ...
This thesis presents the development of Silicon-based nanomaterials for use as the functional compon...
We demonstrate that nanosize silicon (∼10 nm diameter) reacts with water to generate hydrogen 1000 t...
Efficient light stimulated hydrogen generation from top down produced highly doped n type silicon na...
Efficient light stimulated hydrogen generation from top down produced highly doped n type silicon na...
The origin of the photocurrent enhancement and the overpotential reduction in solar water splitting ...
The origin of the photocurrent enhancement and the overpotential reduction in solar water splitting ...
The performance of silicon for water oxidation and hydrogen production can be improved by exploiting...
The performance of silicon for water oxidation and hydrogen production can be improved by exploiting...
International audiencePhotoelectrochemical water splitting is a sustainable and environmentally frie...
International audiencePhotoelectrochemical water splitting is a sustainable and environmentally frie...
International audiencePhotoelectrochemical water splitting is a sustainable and environmentally frie...
International audiencePhotoelectrochemical water splitting is a sustainable and environmentally frie...
International audiencePhotoelectrochemical water splitting is a sustainable and environmentally frie...
Tungsten sulfides, including WS<sub>2</sub> (crystalline) and WS<sub>3</sub> (amorphous), were intro...
In this paper, we report that amorphous silicon oxide nanowires can be grown in a large quantity by ...
This thesis presents the development of Silicon-based nanomaterials for use as the functional compon...
We demonstrate that nanosize silicon (∼10 nm diameter) reacts with water to generate hydrogen 1000 t...