Add to ORKGChemical vapor deposition (CVD) represents an attractive route to synthesize large-area graphene. Its catalytic growth using metals has been studied in recent years, the most popular being nickel and copper. We have successfully grown graphene on copper by CVD at ambient pressure using alcohols as the carbon feedstock. The produced materials are analyzed by SEM, TEM, Raman spectroscopy and transferred onto Si/SiO2 substrates using standard methods. Raman fingerprint of monolayer graphene is present in our samples. This technique represents a safer and more versatile alternative to the production of graphene compared to the synthesis of graphene using methane at low pressure
We report the synthesis of high-quality graphene on Cu foils using hot-filament chemical vapor depos...
Chemical vapor deposition (CVD) is known to produce continuous, large-area graphene sheet with decen...
Large-sized thin-films composed of single- and few-layered graphene have been synthesized by ...
Chemical vapor deposition (CVD) represents an attractive route to synthesize large-area graphene. It...
An original and easy route to produce mono-, bi- and tri-layer graphene is proposed using the chemic...
In the aim to get high quality graphene films, with large domains and free from impurities, minimizi...
Chemical vapor deposition (CVD) is one of the best ways to scalably grow low cost, high quality grap...
Growth of high quality graphene is the basis for the successful demonstration and reduction to pract...
The present work shows a new method in order to cost-effectively achieve the synthesis of graphene b...
Chemical vapor deposition (CVD) is widely utilized to synthesize graphene with controlled properties...
Currently production of large-sized graphene samples is of great importance due to the broad potenti...
Graphene material has attracted much attention from the scientific community for over the last decad...
In this study, different types of graphene, including single-, few-, and multi-layer graphene, were ...
Graphene has been in the spotlight of research activity for the past decade, this two-dimensional la...
Graphene was synthesized at 1000°C by Atmospheric Pressure Chemical Vapor Deposition on copper foil ...
We report the synthesis of high-quality graphene on Cu foils using hot-filament chemical vapor depos...
Chemical vapor deposition (CVD) is known to produce continuous, large-area graphene sheet with decen...
Large-sized thin-films composed of single- and few-layered graphene have been synthesized by ...
Chemical vapor deposition (CVD) represents an attractive route to synthesize large-area graphene. It...
An original and easy route to produce mono-, bi- and tri-layer graphene is proposed using the chemic...
In the aim to get high quality graphene films, with large domains and free from impurities, minimizi...
Chemical vapor deposition (CVD) is one of the best ways to scalably grow low cost, high quality grap...
Growth of high quality graphene is the basis for the successful demonstration and reduction to pract...
The present work shows a new method in order to cost-effectively achieve the synthesis of graphene b...
Chemical vapor deposition (CVD) is widely utilized to synthesize graphene with controlled properties...
Currently production of large-sized graphene samples is of great importance due to the broad potenti...
Graphene material has attracted much attention from the scientific community for over the last decad...
In this study, different types of graphene, including single-, few-, and multi-layer graphene, were ...
Graphene has been in the spotlight of research activity for the past decade, this two-dimensional la...
Graphene was synthesized at 1000°C by Atmospheric Pressure Chemical Vapor Deposition on copper foil ...
We report the synthesis of high-quality graphene on Cu foils using hot-filament chemical vapor depos...
Chemical vapor deposition (CVD) is known to produce continuous, large-area graphene sheet with decen...
Large-sized thin-films composed of single- and few-layered graphene have been synthesized by ...