Thermal Management Materials for Electronics and Energy Systems are crucial for the performance, reliability, and efficiency of advanced technologies. As electronic devices and energy systems continue to evolve, the need for materials that can effectively manage heat has never been more pressing. This session will explore the latest advancements in thermal management materials that enhance the performance and durability of high-performance electronics and energy systems, focusing on innovations that support miniaturization, energy efficiency, and the sustainable operation of next-generation devices.

At MSAM – 2026, this session will bring together thought leaders, researchers, and engineers to discuss the role of thermal management in optimizing the functionality of electronics, energy devices, and systems. These technologies, which span industries from consumer electronics to renewable energy and electric vehicles, all rely on cutting-edge thermal solutions to maintain optimal performance.

We invite submissions and expert talks on:

• Heat Dissipation Materials for Electronics: Exploring innovative materials designed to efficiently transfer heat from high-performance electronic components, including heat sinks, thermal pastes, and phase change materials.

• Thermal Interface Materials (TIMs): Advancements in thermal interface materials that improve heat transfer between electronic components and cooling systems, ensuring efficient energy use and preventing overheating.

• Thermal Management in Power Electronics: Materials and technologies for managing heat in power electronics, including those used in electric vehicles, renewable energy systems, and power distribution.

• Phase Change Materials (PCMs) for Heat Storage and Regulation: How PCMs are revolutionizing thermal management by storing and releasing heat, and their application in energy storage systems, electronics, and HVAC (Heating, Ventilation, and Air Conditioning) systems.

• Graphene and Nanomaterials for Thermal Conductivity Enhancement: The use of graphene and other nanomaterials to create ultra-efficient thermal management solutions for high-power electronics and energy devices.

• Thermal Insulation Materials for Energy Systems: Materials that provide insulation to prevent heat loss in energy systems, improving energy efficiency in sectors like power generation, HVAC, and thermal storage.

• Thermal Management in Batteries and Energy Storage: The role of thermal materials in managing heat in batteries, fuel cells, and other energy storage systems, ensuring longer life cycles and safety.

• Advanced Cooling Solutions for Electronics: The development of innovative cooling solutions, including liquid cooling systems, micro-channel cooling, and heat pipes, to manage the thermal demands of modern electronics.

• Thermal Management in Electric Vehicles (EVs): Materials and technologies used to regulate temperature in electric vehicle batteries, electric motors, and power electronics, optimizing performance and safety.

• Self-Healing Materials for Thermal Management: How self-healing materials are being developed to address thermal degradation in electronics and energy systems, extending their life and improving performance.

• Thermal Conductive Polymers and Composites: The development of advanced polymer-based materials that offer both lightweight and efficient thermal conductivity for electronic devices and energy systems.

• Thermal Management for High-Efficiency LED Lighting and Displays: Innovations in managing heat for energy-efficient lighting and display technologies, ensuring consistent performance and energy savings.

• Energy-Efficient Thermal Management in Renewable Energy Systems: Addressing the thermal challenges in solar power, wind energy, and geothermal systems, and how advanced materials can enhance efficiency and reduce energy loss.

• Thermal Materials in IoT Devices and Wearables: The use of specialized thermal management materials in Internet of Things (IoT) devices, wearables, and sensors to ensure high performance in compact, low-power applications.

• Advanced Materials for Thermal Regulation in Aerospace: The application of advanced thermal materials in aerospace systems, including satellites and spacecraft, where managing extreme temperature variations is crucial.

• Thermal Management in Quantum Computing Systems: Exploring the thermal challenges in quantum computing and how materials science can address issues related to extreme cooling requirements and heat dissipation.

• Innovations in High-Temperature Materials for Electronics and Energy Systems: Developing materials that can withstand extreme temperatures for applications in high-performance energy systems and electronics.

• Smart Thermal Management Systems for Electronics: Integration of smart materials and systems that dynamically adjust thermal properties in response to changes in temperature, improving energy efficiency in real-time.

This session will provide a unique platform for researchers, engineers, and manufacturers to discuss the latest innovations in thermal management materials and explore how these advancements are vital to the continued success of electronics and energy systems. Join us at MSAM – 2026 to delve into the materials that make tomorrow’s devices and energy solutions safer, more efficient, and longer-lasting.