New transfer method of CVD-grown graphene using a flexible, transparent and conductive polyaniline-rubber thin film for organic electronic applications

“…In this context, one approach to graphene production is the Scotch tape-based micromechanical cleavage method developed by Andre Geim and Konstantin Novoselov, who were awarded the 2010 Nobel Prize in Physics [7]. Synthesizing graphene materials by the chemical vapor deposition method (CVD) [8] and epitaxial growth on SiC substrates have also been proven to work [9,10]. However, impurities, grain boundaries, multilayers regions and issues to transfer to a useful substrate might be present.…”

Calcium incorporation in graphene oxide particles: A morphological, chemical, electrical, and thermal study

“…In this context, one approach to graphene production is the Scotch tape-based micromechanical cleavage method developed by Andre Geim and Konstantin Novoselov, who were awarded the 2010 Nobel Prize in Physics [7]. Synthesizing graphene materials by the chemical vapor deposition method (CVD) [8] and epitaxial growth on SiC substrates have also been proven to work [9,10]. However, impurities, grain boundaries, multilayers regions and issues to transfer to a useful substrate might be present.…”

Calcium incorporation in graphene oxide particles: A morphological, chemical, electrical, and thermal study

“…Firstly, the photocatalytic activity of Cu-LAG/TiO 2 composite catalyst might be attributed to extended light absorption into visible light region due to copper and LAG incorporation. Secondly, in Cu-LAG/TiO 2 system, the excited electrons of TiO 2 could transfer from the conduction band to LAG through percolation mechanism [36,37]. Thus, in the composite, LAG served as an acceptor of generated electrons of TiO 2 and effectively suppressed the charge recombination, leaving more charge carriers to form reactive species and promote the H 2 evolution [38].…”

CVD growth of large-area graphene over Cu foil by atmospheric pressure and its application in H2 evolution

“…Graphene, a two-dimensional, single-layer sheet of carbon atoms that are closely packed into a hexagonal lattice structure, is a very promising candidate for high performance photocatalyst because of its excellent thermal conductivity, excellent mobility of charge carriers and large specific surface area [7][8][9]. Because of these unique properties, graphene is showing promise in a diverse range of applications such as sensors [10], transistors [11] and batteries [12].…”

Novel synthesis of quaternary nanocomposites based on chemical vapor grown graphene for photocatalytic hydrogen evolution