Technology
Technology
Technology
Nanoengineering
Nanoengineering
Nanoengineering
We nano-engineer materials and structures to solve the fundamental limitations of traditional batteries.
Create nanomaterials with specific structures that allow faster charging and higher energy density
Generate ultra-thin, functional layers on electrode particles to enhance safety and cycle life
Design the solid electrolyte to overcome low ionic conductivity and poor interfacial contacts
Engineer interfaces (electrode-electrolyte) to improve ion-transport and power density
Manage structural changes that occur during charging and discharging
We nano-engineer materials and structures to solve the fundamental limitations of traditional batteries.
Create nanomaterials with specific structures that allow faster charging and higher energy density
Generate ultra-thin, functional layers on electrode particles to enhance safety and cycle life
Design the solid electrolyte to overcome low ionic conductivity and poor interfacial contacts
Engineer interfaces (electrode-electrolyte) to improve ion-transport and power density
Manage structural changes that occur during charging and discharging
We nano-engineer materials and structures to solve the fundamental limitations of traditional batteries.
Create nanomaterials with specific structures that allow faster charging and higher energy density
Generate ultra-thin, functional layers on electrode particles to enhance safety and cycle life
Design the solid electrolyte to overcome low ionic conductivity and poor interfacial contacts
Engineer interfaces (electrode-electrolyte) to improve ion-transport and power density
Manage structural changes that occur during charging and discharging
Solid Electrolyte
Solid Electrolyte
Solid Electrolyte
Solid electrolyte represents a critical technology in the AI batteries, replacing flammable liquid electrolytes with solid, ion-conducting materials to enhance safety, increase energy density, and enable faster charging.
Current Key Properties
Nonflammable
Flexible
Thin (<20um)
Conductive (5mS/cm)
Electrochemically Stable (ESW>5V)
Thermally Stable (-35oC to 125oC)
Mechanically Stable (M>10MPa)
Stable Interfaces with Electrodes
Chemistry/design is 'Drop-In' Compatible
Sovereign Supply
Solid electrolyte represents a critical technology in the AI batteries, replacing flammable liquid electrolytes with solid, ion-conducting materials to enhance safety, increase energy density, and enable faster charging.
Current Key Properties
Nonflammable
Flexible
Thin (<20um)
Conductive (5mS/cm)
Electrochemically Stable (ESW>5V)
Thermally Stable (-35oC to 125oC)
Mechanically Stable (M>10MPa)
Stable Interfaces with Electrodes
Chemistry/design is 'Drop-In' Compatible
Sovereign Supply
Solid electrolyte represents a critical technology in the AI batteries, replacing flammable liquid electrolytes with solid, ion-conducting materials to enhance safety, increase energy density, and enable faster charging.
Current Key Properties
Nonflammable
Flexible
Thin (<20um)
Conductive (5mS/cm)
Electrochemically Stable (ESW>5V)
Thermally Stable (-35oC to 125oC)
Mechanically Stable (M>10MPa)
Stable Interfaces with Electrodes
Chemistry/design is 'Drop-In' Compatible
Sovereign Supply
Industry-Scale Manufacturing
Industry-Scale Manufacturing
Industry-Scale Manufacturing
Building a perfect solid-state battery in a lab is easy; mass-producing millions of large-format EV cells is a monumental engineering challenge.
AI Battery Solution develops disruptive processes that enable automated and continuous manufacturing. These processes facilitate high-speed, cost-effective production using techniques such as casting to produce thin electrolyte layers, substantially reducing manufacturing costs and improving energy density. We unlock the economics required for true gigafactory scale.
Building a perfect solid-state battery in a lab is easy; mass-producing millions of large-format EV cells is a monumental challenge.
AI Battery Solution develops disruptive processes that enable automated and continuous manufacturing. These processes facilitate high-speed, cost-effective production using techniques such as casting to produce thin electrolyte layers, substantially reducing manufacturing costs and improving energy density. We unlock the economics required for true gigafactory scale.
Building a perfect solid-state battery in a lab is easy; mass-producing millions of large-format EV cells is a monumental engineering challenge.
AI Battery Solution develops disruptive processes that enable automated, continuous manufacturing. These processes facilitate high-speed, cost-effective production using techniques such as casting to produce thin electrolyte layers, substantially reducing manufacturing costs and improving energy density. We unlock the economics required for true gigafactory scale.
AI Battery Solution.
AI Battery Solution.
All Rights Reserved.
All Rights Reserved.