Advancing high-temperature electrostatic energy storage via linker engineering of metal–organic frameworks in polymer nanocomposites These findings offer a rational pathway to harness the exceptional structural diversity of MOFs for the development of composite materials suitable for high-temperature electrostatic energy storage.
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Based on the above results, it is concluded that the bilayered STATR textiles possess extraordinary buffering ability towards sudden temperature changes, this ability is especially beneficial for temperature-adaptive personal thermal regulation under extreme weather conditions, which is highly dependent on the heat storage/release process of BN@PCM core
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Thermal energy storage (TES) using phase change materials (PCMs) is an innovative approach to meet the growth of energy demand. Microencapsulation techniques lead to overcoming some drawbacks of PCMs and enhancing their performances. This paper presents a comprehensive review of studies dealing with PCMs properties and their encapsulation
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Energy storage and conversion are vital for addressing global energy challenges, particularly the demand for clean and sustainable energy. Functional organic materials are gaining interest as
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Organic phase change materials (O-PCMs) such as alkanes, fatty acids, and polyols have recently attracted enormous attention for thermal energy storage (TES) due to availability in a wide range of temperatures and
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In terms of material requirements for energy storage applications, synthesized COFs should possess specific characteristics such as i) high surface area to provide ample active sites for
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Electrochemical energy storage technologies have a profound influence on daily life, and their development heavily relies on innovations in materials science. Recently, high-entropy materials have attracted increasing research interest worldwide. In this perspective, we start with the early development of high-entropy materials and the calculation of the
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Section 2 delivers insights into the mechanism of TES and classifications based on temperature, period and storage media. TES materials, typically PCMs, lack thermal conductivity, which slows down the energy storage and retrieval rate. There are other issues with PCMs for instance, inorganic PCMs (hydrated salts) depict supercooling, corrosion, thermal
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The development of computational simulation methods in high-temperature energy storage polyimide dielectrics is also presented. Finally, the key problems faced by using polyimide as a high-temperature energy storage dielectric material are summarized, and the future development direction is explored.
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Key materials discussed include organic polymers, small molecules, and organic–inorganic hybrids, which have shown promise in battery applications, supercapacitors,
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Due to the advantages of high energy storage density, strong energy storage capacity and constant temperature, PCM has profound advantages in improving efficiency and developing renewable energy, making it an advanced frontier research in the field of energy science and material science in recent years [, , , ].
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The growing interest in energy-efficient buildings has spurred research into the latent heat storage capacity of cementitious materials. This involves incorporating phase change materials (PCMs) within the matrix, allowing the materials to absorb, store, and release thermal energy, thereby moderating temperature fluctuations in buildings , , , .
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fication, thus urging the development of methods that enable more control over the latent heat storage and release. In this Future Energy perspective article, we introduce recently devel
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The building sector is a significant contributor to global energy consumption, necessitating the development of innovative materials to improve energy efficiency and sustainability. Phase change material (PCM)-enhanced concrete offers a promising solution by enhancing thermal energy storage (TES) and reducing energy demands for heating and
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With the rapid development of wearable electronic devices and smart medical care, flexible energy storage has ushered in an unprecedented development. The new material metal-organic framework (MOF) is composed of metal ions and organic ligands through coordination, and has been widely studied for its highly adjustable structure, large specific
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The development of PCEST for agricultural greenhouses is summarized and the future development direction is anticipated. Previous Compared to chemical energy storage materials (metal hydrides, metal hydroxides or metal salt ammonia compounds), PCM is safer and more stable in use, relatively mature in technology, and can be used in most
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(a) Types of thermal energy storage (b) publications with keywords of “Phase Change Material”, “Phase Change Material” + “Encapsulation”, “Phase Change Material + Shape Stabilized” from the year 2010 to 2022 and (c) optimal properties of phase change materials (d) contribution to “Phase Change Material” research by country .
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Energy-efficient components that are capable of intelligently regulating room temperature are much demanded to reduce the energy consumption in buildings. In recent years, phase change materials (PCMs) have been widely investigated for intelligent temperature regulation by taking advantages of their unique thermal, optical, and mechanical properties
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In this Future Energy perspective article, we introduce recently developed optical methods that demonstrate the active control over the latent heat storage in organic PCMs—see the bars in Figure 1 B that mark the windows of light-controlled heat release from novel PCMs. Mechanisms of implementing other triggering stimuli are showcased as
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In the context of the grand strategy of carbon peak and carbon neutrality, the energy crisis and greenhouse effect caused by the massive consumption of limited non-renewable fossil fuels have accelerated the development and application of sustainable energy technologies , , .However, renewable and clean energy (such as solar, wind, etc.) suffers from the
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Phase change materials (PCMs)-based thermal storage systems have a lot of potential uses in energy storage and temperature control. However, organic PCMs (OPCMs)
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Singh P, Sharma RK, Ansu AK, et al. A comprehensive review on development of eutectic organic phase change materials and their composites for low and medium range thermal energy storage applications. et al. In-situ temperature regulation of flexible supercapacitors by designing intelligent electrode with microencapsulated phase change
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The development timeline of AZBs began in 1799 with the invention of the first primary voltaic piles in the world, marking the inception of electrochemical energy storage (Stage 1) , .Following this groundbreaking achievement, innovations like the Daniell cell, gravity cell, and primary Zn–air batteries were devoted to advancing Zn-based batteries, as shown in Fig. 1
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With the development of energy applications, it is critical to explore novel materials that enable more efficient and sustainable energy storage. The structure and pore size of the final products could be tuned by regulating the concentration, pressure, temperature, and duration of reactions. 5 COFS IN ELECTROCHEMICAL ENERGY STORAGE
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In particular, the melting point, thermal energy storage density and thermal conductivity of the organic, inorganic and eutectic phase change materials are the major
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Vol.:(0123456789)1 3 Food Measure DOI 10.1007/s11694-017-9672-5 ORIGINAL PAPER Temperature-regulating materials for advanced food packaging applications: a review
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So the right type of material is needed to store thermal energy to meet energy requirements. 7–10 The desired characteristics of thermal energy storage materials are large storage capacity per unit mass, high ability to undergo charging and discharge, stability in the operating temperature range, inexpensiveness, and long durability. 11–14 PCMs can be utilized for solar thermal energy
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However, the density of material energy storage is relatively low, the volume of equipment is relatively large, the stored heat energy cannot be released at a certain temperature when releasing heat energy, and its temperature change is continuous [11, 12]; Phase change (latent heat) heat storage technology is to store and release heat by using the change of latent
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Research and development of multi-temperature zone cold energy storage device and cold energy storage packaging, improve cooling rate and quality of aquatic products, prolong the shelf life of aquatic products, reduce energy consumption and operating costs, is the research on the application of phase change cold energy storage materials in cold chain logistics of
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Aydin, A.A. Diesters of high-chain dicarboxylic acids with 1-tetradecanol as novel organic phase change materials for thermal energy storage. Sol. Energy Mater.
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The review covers various types of organic materials, including organic polymers, small molecules, and organic–inorganic hybrids, that have shown promising performance in energy storage and conversion devices.
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In this future energy article, we introduce an optomechanical method that allows for controlling low-grade waste heat storage and release in organic phase change materials. Nanoscale molecular switches that change
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Phase change thermal energy storage has the advantages of high safety performance, low-cost, high-energy storage density, good stability, small volume change, and small range of temperature variation [4,5,55]. One of the key points in phase change thermal energy storage is to detect suitable and applicable phase change materials (PCMs).
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First of all, by integrating multiple functions such as light modulation, energy harvesting, storage, and conversion, ECDs significantly improve overall efficiency and utility, reducing the need for separate devices therefore saving space and costs , sides, the growing emphasis on environmental sustainability and the push for green technologies have
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The research on phase change materials (PCMs) for thermal energy storage systems has been gaining momentum in a quest to identify better materials with low-cost, ease of availability, improved thermal and chemical stabilities and eco-friendly nature. The present article comprehensively reviews the novel PCMs and their synthesis and characterization techniques
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The issue of energy scarcity has become increasingly severe due to the ongoing progress of social and economic development. Rising fuel prices and escalating greenhouse gas emissions have underscored the urgent need for efficient utilization of diverse renewable energy sources [, , ].However, renewable energy sources often suffer from the drawback of
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Thermal energy storage technology of liquidsolid phase change materials (LSPCMs) is one of the most attractive thermal energy storage technologies due to its high energy storage density, low
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Finally, we outline the current challenges and future development directions of PI-based high-temperature energy storage dielectric materials. Polyimide (PI) has received great attention for high-temperature capacitive energy storage materials due to its remarkable thermal stability, relatively high breakdown strength, strong mechanical properties, and ease of synthesis and
Learn MorePhase change materials (PCMs)-based thermal storage systems have a lot of potential uses in energy storage and temperature control. However, organic PCMs (OPCMs) face limitations in terms of regulating phase change temperature, low thermal conductivity, and inadequate functionality for diverse applications.
The limited application of organic polymers in phase change energy storage is attributed to their low thermal conductivity . This limitation primarily arises because heat transfer in non-metallic materials, such as organic polymers, depends on elastic waves from lattice vibrations, known as phonon energy transfer, .
J. Chem. Eng. Data 2015, 60, 202–212. [Google Scholar] Aydin, A.A. Diesters of high-chain dicarboxylic acids with 1-tetradecanol as novel organic phase change materials for thermal energy storage. Sol. Energy Mater.
As research and development continue to advance in this field, organic materials are expected to play an increasingly pivotal role in shaping the future of technology and innovation. To fully harness the potential of functional organic materials in energy storage and conversion, future research efforts should prioritize several key areas.
Journal portfolios in each of our subject areas. Links to Books and Digital Library content from across Sage. Organic phase change materials (O-PCMs) such as alkanes, fatty acids, and polyols have recently attracted enormous attention for thermal energy storage (TES) due to availability in a wide range of temperatures and high latent heat values.
Aydin, A.A. Diesters of high-chain dicarboxylic acids with 1-tetradecanol as novel organic phase change materials for thermal energy storage. Sol. Energy Mater. Sol. Cells 2012, 104, 102–108. [Google Scholar]
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