Glassy Carbon Foam for Battery and Supercapacitor Research, Purity: 95+%, Size: 100 mm x100 mm x 10 mm

Technical Specification:

1. Material Composition:
   • Material: Glassy Carbon.
     • Purity: 95+%, providing high conductivity and chemical stability.
2. Physical Dimensions:
   • Size: 100 mm x 100 mm x 10 mm.
     • Suitable for a variety of electrode configurations in energy storage research.
   • Thickness: 10 mm.
     • Offers substantial volume for active material loading.
3. Structural Properties:
   • Porosity: Typically 85–95%, with an open-cell structure.
     • High porosity maximizes surface area for electrochemical activity.
   • Pore Size: Uniform micropores to macropores for optimal ion transport and electrolyte infiltration.
   • Density: Lightweight structure minimizes overall device weight.
4. Thermal and Mechanical Properties:
   • Thermal Stability:
     • Resistant to high temperatures (up to 600°C in inert atmospheres).
   • Mechanical Strength:
     • Rigid structure supports repeated charge/discharge cycles without deformation.
5. Electrical Properties:
   • High Conductivity:
     • Facilitates efficient electron transport, enhancing device performance.
   • Low Resistance:
     • Minimizes energy loss during operation.
6. Chemical Properties:
   • Corrosion Resistance:
     • Inert in most electrolytes, including acidic, basic, and organic environments.
   • Electrochemical Stability:
     • Compatible with various electrode chemistries and electrolytes.
7. Processing Capabilities:
   • Can be cut, shaped, or coated with active materials to meet specific research needs.

Applications:

1. Primary Applications:
   • Electrode Material:
     • Acts as a conductive substrate or current collector for active materials in batteries and supercapacitors.
2. Industries:
   • Battery Research and Development:
     • Supports the prototyping and testing of lithium-ion, sodium-ion, and other advanced batteries.
   • Supercapacitor Innovation:
     • Used in high-power, high-capacitance energy storage devices.
   • Energy Storage Systems (ESS):
     • Applied in grid-scale or renewable energy storage solutions.
   • Electrochemical Research:
     • Facilitates studies in catalysis, corrosion resistance, and material characterization.
3. Advantages for Applications:
   • High Surface Area:
     • Promotes active material interaction, enhancing charge storage capacity.
   • Electrical Conductivity:
     • Provides efficient electron pathways, reducing internal resistance.
   • Chemical Inertness:
     • Ensures stability and durability in harsh electrochemical environments.
   • Thermal Stability:
     • Supports high-temperature processes and applications.
4. Specialized Uses:
   • Solid-State Batteries:
     • Serves as a rigid substrate for solid electrolytes and advanced electrodes.
   • High-Performance Supercapacitors:
     • Ideal for supporting high-capacitance materials such as carbon nanotubes or graphene.
   • Catalyst Support:
     • Acts as a conductive scaffold for electrocatalysts in fuel cells and water splitting applications.
5. Challenges and Mitigation:
   • Brittleness:
     • Glassy carbon can be brittle and prone to cracking under excessive mechanical stress.
       • Solution: Handle with care and avoid excessive force during cutting or shaping.
   • Cost:
     • Higher cost compared to traditional current collectors.
       • Solution: Use selectively in high-performance or research-intensive applications.

Summary:

The Glassy Carbon Foam for Battery and Supercapacitor Research, with a purity of 95+% and dimensions 100 mm x 100 mm x 10 mm, is a high-performance material for advanced energy storage applications. Its high porosity, excellent conductivity, and chemical stability make it ideal for use as an electrode substrate or current collector in lithium-ion batteries, solid-state batteries, and supercapacitors. This material is critical for developing cutting-edge technologies in energy storage and electrochemical research.