Graphene Transferred onto Glass Substrate (1 cm × 2 cm)

Description

Graphene Transferred onto Glass Substrate (1 cm × 2 cm)

CAS Number: 7782-42-5

Substrate Size: 1 cm × 2 cm

Preparation Method: Graphene film is grown on copper foils via Chemical Vapor Deposition (CVD) and transferred onto glass substrates using a PMMA (polymethyl methacrylate) layer and wet chemical transfer techniques.

Morphology Options:
Continuous Monolayer Film
Continuous Multilayer Film
For specific requirements, please contact us directly.

Substrate Options:
Graphene film is transferred onto glass substrates. Custom transfer to other substrate materials is available upon request—please visit our Custom Products page or contact us for assistance.

Fundamental Properties:
Graphene film transferred onto glass substrates retains its exceptional electronic, optical, and mechanical properties, while leveraging the insulating and transparent properties of the glass substrate. The PMMA-assisted transfer ensures high-quality, uniform graphene films with minimal defects, making it suitable for advanced optoelectronic and sensing applications. Key properties include:

Electrical Properties (Graphene): High electrical conductivity with carrier mobility exceeding 10,000 cm²/V·s.
Optical Transparency: Graphene on glass transmits ~97.7% of visible light, enabling its use in transparent and optoelectronic devices.
Mechanical Properties: Exceptional strength and flexibility, with a tensile strength of ~130 GPa, suitable for robust yet lightweight designs.
Thermal Properties: High thermal conductivity of graphene allows for efficient heat dissipation, ideal for high-performance devices.
Applications:

Optoelectronics: Ideal for transparent conductive films in displays, touchscreens, and photovoltaic devices, leveraging the insulating and transparent nature of the glass substrate.
Sensors: Graphene on glass is highly sensitive for detecting gases, chemicals, and biological molecules due to its conductive and high-surface-area properties.
Energy Applications: Utilized as transparent electrodes in energy storage devices, such as supercapacitors and batteries, where the glass substrate provides stability and transparency.
Coatings and Photonics: Graphene on glass can be used as a conductive layer for enhancing optical devices and protective coatings.