Titanium Crucibles in Energy Applications- Fuel Cells, Hydrogen Storage, and Batteries
                     Titanium Crucibles in 
Energy Applications: 
Fuel Cells, Hydrogen 
Storage, and 
Batteries
Submitted By:
M-Kube Enterprise Pty Ltd
Introduction
• Growing demand for advanced energy systems requires durable, corrosion-resistant 
crucibles.
• Titanium crucibles are ideal due to their strength, purity, and resistance to aggressive 
environments.
• Applications:
• Fuel cell research
• Hydrogen storage materials
• Battery electrode and electrolyte studies
Properties of 
Titanium 
Crucibles
• High melting point: ~1668 °C
• Excellent resistance to corrosion, 
halides, and molten salts
• Biocompatible and chemically inert
• Available in high purity titanium 
crucibles for sensitive experiments
Makes crucible titanium a key 
material for modern energy labs
Types of Titanium Crucibles
• Titanium Metal Crucible – general high-temperature applications
• High Purity Titanium Crucible – critical for contamination-free energy material 
synthesis
• Titanium Crucible for Metallurgy – used in alloy and hydrogen storage material 
development
• Titanium Crucible for Laboratory Use – small-scale fuel cell and battery research
Researchers often buy titanium crucibles from specialized titanium crucible 
suppliers
Role in Fuel Cells
• Used for catalyst preparation and sintering of fuel cell electrodes
• Crucible stability prevents contamination in proton exchange membrane 
(PEM) fuel cell research
• Supports synthesis of ceramic electrolytes (YSZ, doped ceria) in solid oxide 
fuel cells (SOFCs)
Titanium crucible ensures purity and durability in high-temperature fuel cell 
testing
Role in Hydrogen Storage 
Research
• Hydrogen storage materials: metal hydrides, complex hydrides, carbon-
based nanomaterials
• Titanium metal crucibles used in:
• Hydrogen sorption studies
• Material cycling experiments
• Thermal stability testing
• High purity titanium crucibles minimize interference during hydride 
formation
Role in Battery Applications
• Critical in lithium-ion, sodium-ion, and solid-state batteries
• Applications:
• Electrolyte melting & solid-state synthesis
• High-temperature stability of cathode/anode materials
• Testing advanced solid electrolytes (sulfides, oxides)
Titanium crucible for laboratory use supports R&D in next-gen batteries
Titanium Crucible for Metallurgy 
in Energy Materials
• Used in alloy development for hydrogen storage (Ti-based alloys, Mg-Ti 
composites)
• Supports powder metallurgy in electrode material production
• Ensures controlled microstructure and purity in high-energy alloys
Market & Supply 
Considerations
• Availability: Wide range of titanium crucible suppliers globally
• Options: custom sizes, lids, and coatings
• Cost factors:
• Purity level
• Size & shape (cylindrical, conical, boat crucibles)
• Supplier reputation
Industries and labs often evaluate titanium crucible price vs. performance 
before purchase
Advantages of Using Titanium 
Crucibles
• High chemical stability in aggressive environments
• No contamination during material synthesis
• Long life cycle compared to ceramic crucibles
• Compatible with fuel cell, hydrogen, and battery R&D
Challenges & Limitations
• High cost compared to alumina or graphite crucibles
• Limited availability of large-size titanium crucibles
• Requires specialized machining & fabrication techniques
Conclusion
• Titanium crucibles are indispensable in energy material research.
• Applications span fuel cells, hydrogen storage, and batteries.
• Choosing the right titanium crucible supplier ensures quality, durability, 
and cost-effectiveness.
A strategic material for the clean energy revolution.