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Lauric acid based form-stable phase change material for effective electronic thermal management and energy storage application

Poor thermal management in electronic systems can lead to higher junction temperatures, accelerating failure mechanisms and reducing component lifespan. Integrating efficient thermal management techniques, such as heat sinks, is essential for ensuring durability and efficiency of electronic equipmen...

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Bibliographic Details
Main Authors: Bhutto Y.A., Pandey A.K., Islam A., Rajamony R.K., Saidur R.
Other Authors: 58491549600
Format: Article
Published: Elsevier Ltd 2025
Subjects:
Additives
Boron nitride
Economic and social effects
Electronic cooling
Failure (mechanical)
Heat sinks
Heat storage
III-V semiconductors
Latent heat
Storage (materials)
Temperature control
Thermal conductivity
Thermal management (electronics)
Electronics cooling
Electronics system
Electronics thermal managements
Energy storage applications
Expanded graphite
Form stabilities
Form stable phase change material
Higher junction temperatures
Lauric acid
Thermal energy storage
Phase change materials
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Summary:Poor thermal management in electronic systems can lead to higher junction temperatures, accelerating failure mechanisms and reducing component lifespan. Integrating efficient thermal management techniques, such as heat sinks, is essential for ensuring durability and efficiency of electronic equipment. Heat sinks have limited capacity, but integrating phase change materials (PCMs) enhances cooling performance by harnessing latent heat storage. However, leakage and low thermal conductivity limit PCM's effectiveness. The current study developed highly conductive leakage-proof PCMs based composites using an ultrasonic and vacuum impregnation method with lauric acid as base, hexagonal boron nitride and expanded graphite as additives. The results demonstrate persistence of chemical integrity, as proven by FTIR analysis, and complete encapsulation of PCMs inside the expanded graphite structures. The form-stable composite PCMs exhibit a 450% increase in thermal conductivity and 77% photo-transmittance decrease compared to base PCMs. Despite a trade-off of a 11.5% reduction in latent heat, the composite demonstrates thermal stability up to 220 �C. Further, excellent chemical and thermal reliability is maintained even after 500 cycles. Furthermore, in thermal management for heat sink, the form stable composite efficiently dispersed heat, resulting in a 16 �C decrease in peak temperature compared to the heat sink without the composite. ? 2024 Elsevier Ltd

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