Titanium Foam for Battery and Supercapacitor Research, Purity: 99+%, Size: 100 mm x100 mm x 2.8mm

Technical Specification:

1. Material Composition:
   • Material: Titanium (Ti).
     • Purity: 99+%, ensuring minimal contamination and optimal electrochemical properties.
2. Physical Dimensions:
   • Size: 100 mm x 100 mm x 2.8 mm.
     • Suitable for various electrode configurations in battery and supercapacitor research.
   • Thickness: 2.8 mm.
     • Provides a balance between structural strength and surface area.
3. Structural Properties:
   • Porosity: Typically 60–95% depending on manufacturing process.
     • High porosity offers a large surface area for improved electrochemical activity.
   • Pore Size: Micro- to macropores for efficient ion transport and electrolyte accessibility.
   • Lightweight: Low density due to porous structure.
4. Thermal and Mechanical Properties:
   • Thermal Conductivity:
     • Excellent heat dissipation to prevent overheating in electrochemical applications.
   • Mechanical Strength:
     • Robust structure supports repeated charge/discharge cycles without degradation.
5. Chemical Properties:
   • Corrosion Resistance:
     • Resistant to chemical attack, ensuring long-term stability in harsh battery environments.
   • Electrochemical Stability:
     • Compatible with various battery and supercapacitor chemistries.
6. Processing Options:
   • Can be cut, shaped, or coated to suit specific research requirements (e.g., applying active materials or catalysts).

Applications:

1. Primary Applications:
   • Electrode Substrate:
     • Used as a current collector or substrate for active materials in batteries and supercapacitors.
2. Industries:
   • Battery Research and Development:
     • Supports prototyping and testing of advanced lithium-ion, sodium-ion, and solid-state batteries.
   • Supercapacitor Innovation:
     • Enhances performance in energy storage devices requiring high power density.
   • Energy Storage Systems (ESS):
     • Applied in modular systems for grid storage or renewable energy integration.
   • Electrochemical Research:
     • Useful in corrosion studies, catalysis, and advanced material characterization.
3. Advantages for Applications:
   • High Surface Area:
     • Increases active material loading and improves electrochemical performance.
   • Corrosion Resistance:
     • Ensures durability in aggressive electrolytes.
   • Lightweight:
     • Contributes to the development of lightweight and portable energy storage devices.
   • Thermal Management:
     • Efficiently dissipates heat during high-power applications.
4. Specialized Uses:
   • Solid-State Batteries:
     • Acts as a robust substrate for solid electrolytes and advanced electrodes.
   • Advanced Supercapacitors:
     • Provides a conductive framework for high-capacitance materials like carbon or graphene.
   • Electrocatalysis:
     • Supports catalysts for water splitting, fuel cells, or other electrochemical reactions.
5. Challenges and Mitigation:
   • Surface Preparation:
     • May require cleaning or surface treatments before applying active materials.
       • Solution: Use ultrasonic cleaning or chemical etching for optimal preparation.
   • Cost:
     • Titanium foam is more expensive than traditional current collectors.
       • Solution: Use selectively in high-performance or research applications.

Summary:

The Titanium Foam for Battery and Supercapacitor Research, with a purity of 99+% and dimensions 100 mm x 100 mm x 2.8 mm, is a versatile and high-performance material. Its high porosity, corrosion resistance, and thermal stability make it ideal for advanced energy storage applications. It is widely used as an electrode substrate in lithium-ion batteries, solid-state batteries, and supercapacitors, supporting innovations in portable electronics, electric vehicles, and renewable energy systems.