Cell Lab Nickel Mesh [Nickel Mesh Electrode | Current Collector | Catalyst Support 100 × 100 × 0.05 mm, 100 Mesh]

Cell Lab Nickel Mesh [Nickel Mesh Electrode | Current Collector | Catalyst Support 100 × 100 × 0.05 mm, 100 Mesh]

High-conductivity nickel mesh for electrochemical research, catalyst support, and battery electrode applications

The Cell Lab Nickel Mesh is engineered for advanced energy and electrochemical research where high electrical conductivity, corrosion resistance, and flexibility are essential. Made from ≥ 99.5 % pure nickel, this precision 100-mesh structure offers excellent porosity (~ 0.18 mm) and mechanical strength. It serves as an ideal current collector, electrode substrate, or catalyst carrier in batteries, fuel cells, supercapacitors, and other functional materials research.

Key Features

• High-Purity Nickel (≥ 99.5 %): Provides outstanding chemical stability and minimal contamination during electrochemical reactions.

• Precision Mesh Structure (100 Mesh): Uniform ~ 0.18 mm pores ensure consistent ion and gas transport.

• Flexible & Lightweight Design: Easy to shape, cut, and integrate into cell assemblies and lab prototypes.

• Excellent Corrosion Resistance: Maintains conductivity and integrity in acidic and alkaline electrolytes.

• Versatile Applications: Ideal for batteries, fuel cells, catalysts, supercapacitors, and solar energy systems.

Technical Specifications

Applications & Industries

• Lithium-ion and solid-state battery current collectors

• Supercapacitor electrode substrates

• Fuel-cell and catalyst support materials

• Photocatalysis and solar energy devices

• Electrode and sensor fabrication research

FAQ

Q1: What is the purity level of this nickel mesh?
It is made from ≥ 99.5 % high-purity nickel for excellent stability and conductivity.

Q2: Can the mesh be customised?
Yes. Cell Lab can tailor mesh count, thickness, and size upon request.

Q3: Is it suitable for electrochemical testing?
Absolutely. It is commonly used as a current collector and electrode substrate in battery and fuel-cell experiments.

Q4: How should it be handled and stored?
Keep in a dry environment and avoid strong acids to preserve surface quality.

Q5: Can it be used as a catalyst support?
Yes. Its porous structure and chemical resistance make it ideal for catalyst coating and reaction studies.