Andere Kunden interessierten sich auch für
![Solar Cells: Wafer Bonding and Plasmonic]( "Solar Cells: Wafer Bonding and Plasmonic")
Solar Cells: Wafer Bonding and Plasmonic29,99 €![Chalcogenides for photovoltaic applications]( "Chalcogenides for photovoltaic applications")
Chalcogenides for photovoltaic applications47,99 €![Dielectric Materials:Barium Titanate]( "Dielectric Materials:Barium Titanate")
Dielectric Materials:Barium Titanate29,99 €![Harnessing the power of Sun]( "Harnessing the power of Sun")
Harnessing the power of Sun29,99 €![CVD of Carbon Thin Films and Micro/Nano-structures]( "CVD of Carbon Thin Films and Micro/Nano-structures")
CVD of Carbon Thin Films and Micro/Nano-structures39,99 €![Investigation of InSe Thin Film Based Devices]( "Investigation of InSe Thin Film Based Devices")
Investigation of InSe Thin Film Based Devices45,99 €![CIGS Absorber Layer for Solar Cell]( "CIGS Absorber Layer for Solar Cell")
CIGS Absorber Layer for Solar Cell43,99 €
Graphene's superior carrier mobility, optical transparency, and thermal conductivity make it a one-of-a-kind material for creating 2D-physics devices in electrical and optoelectronics. Top-down and bottom-up physical and chemical processes are used to create graphene layers. Polycrystalline Cu foils are better at controlling large area expansion and layer number while having low defects. Wet transfer was used to transfer graphene from one side to quartz and suspend graphene on a TEM Cu grid. Low-temperature PVD was used to create various ZnO nanorods, nanowires, and nanoribbons on single- and multilayer graphene.