Lithium Battery Applications1

KARGEN | Innovative MOF Solutions for Lithium Batteries

About the Solution
With the rapid development of new energy vehicles and energy storage systems, lithium batteries face increasing demands for energy density, cycle life, and safety. KARGEN integrates the unique structure and performance of MOF materials into the lithium battery industry chain, developing solutions for transition metal ion capture, lithium dendrite suppression, separator coating modification, and solid-state electrolytes. Our material innovations address core industry pain points, enabling comprehensive performance upgrades for lithium batteries.

Key Application Scenarios

Transition Metal Ion Capture

During battery cycling, positive electrode materials release transition metal ions that catalyze electrolyte decomposition, reducing battery life and safety. Customized MOF materials efficiently capture these ions through synergistic physical and chemical adsorption, preventing damage to electrolytes and electrodes without affecting lithium ion transport.
Lithium Dendrite Suppression

Lithium dendrite growth on the negative electrode can pierce the separator, causing short circuits and thermal runaway. MOF materials modified on the negative electrode or integrated into separators guide uniform lithium ion deposition, inhibiting dendrite formation while maintaining good electrochemical stability and electrolyte compatibility.
Battery Separator Coating Modification

Traditional polyolefin separators suffer from poor thermal stability and electrolyte wettability. MOF-based composite coatings enhance separator performance, improving electrolyte absorption, thermal stability, and mechanical strength. The coating is compatible with existing production lines without additional equipment modifications.
MOF-Based Solid-State Electrolytes

Liquid electrolytes pose leakage and flammability risks. MOF-based solid-state electrolytes use MOF frameworks as lithium ion transport channels, offering high ionic conductivity, good mechanical strength, and thermal stability. They address interface impedance issues, enabling safer and higher energy density batteries.

Core Competitiveness

Extended Cycle Life
Reduce electrolyte decomposition and negative electrode wear, significantly extending battery service life

Enhanced Safety
Prevent thermal runaway, short circuits, and electrolyte leakage, improving battery safety

Optimized Electrochemical Performance
Improve first-cycle efficiency, rate performance, and energy density for better battery performance

Environmental & Cost Advantages
Fluorine-free and solvent-free materials comply with environmental standards, with lower costs than competitors

Cooperation & Support

Supply of standardized MOF materials for transition metal capture, separator coating, and solid-state electrolytes
Customized development of MOF materials based on battery type (power, energy storage, consumer) and performance requirements
Technical collaboration for lithium battery upgrading, including process optimization and production line adaptation
Joint R&D through laboratory co-construction to tackle key technical challenges and share research outcomes