Ceramics

The Role of Ceramic Thermal Media

Ceramic thermal media provide a solid-state alternative to fluid-based thermal storage and heat distribution.

Designed to operate at high temperatures and respond rapidly to induction heating, advanced ceramic media enable precise, controllable thermal management across energy and industrial systems.

Unlike fluid-based storage, ceramic media:

• eliminate freeze risk

• decouple storage from chemistry

• enable localized thermal control

Induction-Responsive by Design

Thermal Nano Technology develops ceramic materials engineered for efficient electromagnetic coupling.

These materials are designed to:

• respond rapidly to induction heating

• distribute heat uniformly

• tolerate repeated thermal cycling

• operate across a wide temperature range
  
  

Induction enables heat to be added exactly where and when it is required, without heating surrounding structures or introducing intrusive internal elements.

Flexible Physical Forms

Ceramic media are engineered in multiple physical formats to match system requirements:

· Spherical and near-spherical media for bulk thermal storage
· Structured blocks and honeycomb geometries for controlled flow paths
· Cylindrical and finned elements for heat exchange and distribution
· Custom geometries optimized for specific industrial applications

Form factor selection allows systems to balance:

• heat transfer rate

• thermal mass

• mechanical handling

• flow characteristics
  
  

Applications Across Energy and Industry

Advanced ceramic thermal media support a wide range of applications:

· High-temperature thermal storage
· Controlled heat delivery to power and process systems
· Industrial furnaces and reactors
· HVAC and energy recovery systems
· CSP and hybrid thermal platforms

Ceramic media operate independently of salt chemistry, pressure, or phase-change constraints.

Designed for Modular Systems

Ceramic thermal media are designed to integrate seamlessly into modular, serviceable system architectures.

• Compatible with modular storage tanks and process trains

• Easily removed, replaced, or reconfigured

• Scalable from pilot systems to full industrial deployment

• Supports N+1 redundancy and fault isolation
  
  

Thermal capacity scales by adding media, not redesigning infrastructure.

Protecting the Core Technology

Material composition, doping strategies, and manufacturing methods are protected through patent-pending designs.

Public information focuses on system behavior and architectural value, while proprietary material science remains confidential.

Why Ceramics Matter

By combining induction-responsive ceramic media with modular system architecture, Thermal Nano Technology enables:

· Precise thermal control
· Elimination of freeze-related failure modes
· Reduced reliance on fluid-based storage
· Higher system availability and longevity

Ceramics form the foundation for next-generation thermal systems designed for real-world operation.