HomeProductsApplicationsServicesQualityAboutKnowledgeContact

Anode Active Material

Lithium titanate (LTO)

LTO is selected for high-power, long-cycle-life, and safer anode systems where higher anode potential is acceptable.

Li4Ti5O12

Product Details

Lithium titanate (LTO)

Category
Anode Active Material
Availability
RFQ
Grade
Commercial lithium titanate anode powder
Documents
SDS / COA / TDS

Typical Specification

  • D50 typically 0.5-2 um
  • Specific capacity typically 160-175 mAh/g
  • Rate grade and surface area to be confirmed
  • Moisture typically <=500 ppm

Specifications vary by grade and production lot. Confirm the applicable COA or TDS, sampling method, and acceptance limits before cell qualification.

Use Cases

  • LTO is selected for high-power, long-cycle-life, and safer anode systems where higher anode potential is acceptable.
  • Requested materials can be quoted for R&D, pilot-scale qualification, or production-scale sourcing after grade, particle-size, documentation, and packaging requirements are confirmed.
  • Typical supporting documents may include SDS, COA, and TDS depending on supplier lot and requested specification.

Back to Battery Active Materials

Technical Selection Guide

How should Lithium titanate (LTO) be evaluated?

Lithium titanate (LTO) is a lithium-ion anode with a relatively high operating potential and strong structural stability. LTO is used where power, cycle life, safety, and low-temperature operation can be more important than maximum cell voltage.

Why developers evaluate it

  • High-power and long-life lithium-ion cells
  • Low-temperature and fast-charge studies
  • Electrolyte gas and high-voltage pairing tests

Development considerations

  • Lower full-cell voltage reduces energy density
  • Gas generation can depend on electrolyte and storage conditions
  • Particle size and electrode density affect rate performance

How to compare it

Compare LTO with graphite using application-level energy, power, temperature, and lifetime targets. LTO often improves kinetic and safety margins while sacrificing nominal cell voltage.

Battery Active Materials Battery Applications Material Selection & Screening Support