Composite phase change material (CPCM) has great potential in addressing the challenges associated with thermal energy storage and thermal management.
Polyurethane (PU) based phase change materials (PCMs) undergo the solid–solid phase transition and offer state-of-the-art thermal energy storage
Polyurethane-based solid-solid phase change materials with in situ reduced graphene oxide for light-thermal energy conversion and storage
Organic phase change materials (PCMs), with inherent capability to charge and discharge latent heat via solid–liquid phase transformation, have obtained significant progress
The Innovation Energy 1(3): 100036. Phase change materials (PCMs) have been broadly researched in thermal energy storage fields due to their high latent heat and reversible
Preparation of flexible solid-solid phase change materials with simultaneously thermal energy storage capability, reprocess ability and dual-actuated shape memory
A composite solid-solid phase change material (SSPCM-CNT) with high thermal conductivity and stability was then prepared by incorporating CNT-OH. A battery thermal
The solid–solid phase change materials (SSPCMs) have become the preferred materials in thermal energy storage via absorbing latent heat from ambient environment.
Polyurethane solid-solid phase change materials based on triple dynamic bonds with excellent mechanical and self-healing properties for
To achieve the goal of carbon neutrality, efficient use of solar energy is feasible and imminent. The selection of phase change materials (PCMs) as energy storage media is an
In conclusion, the composite solid-solid phase change material prepared in this paper has good thermodynamic and mechanical properties, and is expected to become a
Conventional solid–solid phase-change materials (SSPCMs) exhibit good thermal energy storage (TES) ability and shape stability, but they cannot be recycled
Phase change materials (PCMs) exhibit significant potential for overcoming the issues related to thermal energy storage and management.
Abstract Phase change materials (PCMs) show substantial promise in regulating the supply and demand of renewable energy and in recovering and utilizing waste heat.
A supramolecular polymeric solid–solid phase change material with high latent heat storage and superior mechanical strength is developed for
As the global energy crisis intensifies, the development of solar energy has become a vital area of focus for many nations. The utilization of phase change
Phase change materials (PCMs) have received great attention in thermal management of electronic devices due to their high energy storage density and no need for
Polyethylene glycol (PEG)-based solid–solid phase change materials (SSPCMs) were first synthesized using PEG and hexamethylene
Abstract Solid-solid phase change fibers are advantageous for thermal management and latent heat storage, because they don''t have the issue of liquid leakage
Phase-change materials (PCMs) ofer tremendous potential to store thermal energy during reversible phase transitions for state-of-the-art applications.
A series of polystyrene graft palmitic acid (PA) copolymers as novel polymeric solid–solid phase change materials (PCMs) were synthesized. In solid–solid PCMs,
Herein, the aim is to provide a holistic analysis of solid–solid PCMs suitable for thermal-energy harvesting, storage, and utilization. The
Thermal energy storage using phase change materials (PCMs) offers enormous potential for regulation of unmatched energy supply and demand of renewable energy
Compared to solid-liquid phase change energy storage, solid-solid phase change energy storage offers better volumetric stability, thermal stability, a
Polyethylene glycol (PEG) is an important and popular phase change material (PCM), but is not a good antistatic material, which would
Polyurethane (PU) based phase change materials (PCMs) undergo the solid–solid phase transition and offer state-of-the-art thermal energy storage (TES). Nevertheless, the exploration
Phase change materials (PCMs) with energy-saving and sustainable energy potential are widely available for energy storage technologies. At present,
<p>The practicality of conventional solid–liquid phase change materials (PCMs) is adversely restricted by liquid phase leakage, large volume expansion, shape instability, and severe
In recent years, graphene has been introduced into phase change materials (PCMs) to improve thermal conductivity to enhance the heat transfer efficiency
The decomposition of TPUPCM starts and reaches a maximum at 323.5 °C and 396.2 °C, respectively. Furthermore, the solid–solid phase-change material is dissolvable,
Phase change materials (PCM) have a potential role in thermal energy storage applications. Recent progress has shown notable work on solid
Phase change materials (PCM) have been widely used in thermal energy storage fields. As a kind of important PCMs, solid-solid PCMs possess unique advantages of low
