Photo- and magneto-responsive highly graphitized carbon based phase change composites for energy conversion and storage

“…(B) Mechanism of magnetic-thermal conversion of MOF-derived carbon-based composite PCMs. Reproduced with permission from ref . Copyright 2022, Elsevier.…”

“…More importantly, MOF-derived magnetic nanoparticles can be highly dispersed in the carbon matrix. Our group 213 designed MOF-derived magnetic-thermal composite PCMs for the first time, where MOF-derived magnetic cobalt-decorated highly graphitized carbon served as a supporting material. Numerous sp 2 carbon atoms and π electrons existed in the graphitic carbon structure.…”

“…The compositions, morphologies, and sizes of MOFderived carbon can also be regulated by selecting different MOF precursors, carbonization temperatures, and calcination atmosphere, which has become a research hotspot in the field of solarthermal energy conversion. 212 Chen et al 213 prepared magnetic highly graphitized carbon skeleton derived from Co-MOF via a high-temperature calcination strategy, followed by the encapsulation of octadecanol. The resultant carbon-based composite PCMs showed a high solar-thermal conversion efficiency of 88.1% due to the synergistic conjugate effect of highly graphitized carbon and local surface plasmon resonance (LSPR) effect of Co nanoparticles.…”

Phase Change Thermal Storage Materials for Interdisciplinary Applications

“…(B) Mechanism of magnetic-thermal conversion of MOF-derived carbon-based composite PCMs. Reproduced with permission from ref . Copyright 2022, Elsevier.…”

“…More importantly, MOF-derived magnetic nanoparticles can be highly dispersed in the carbon matrix. Our group 213 designed MOF-derived magnetic-thermal composite PCMs for the first time, where MOF-derived magnetic cobalt-decorated highly graphitized carbon served as a supporting material. Numerous sp 2 carbon atoms and π electrons existed in the graphitic carbon structure.…”

“…The compositions, morphologies, and sizes of MOFderived carbon can also be regulated by selecting different MOF precursors, carbonization temperatures, and calcination atmosphere, which has become a research hotspot in the field of solarthermal energy conversion. 212 Chen et al 213 prepared magnetic highly graphitized carbon skeleton derived from Co-MOF via a high-temperature calcination strategy, followed by the encapsulation of octadecanol. The resultant carbon-based composite PCMs showed a high solar-thermal conversion efficiency of 88.1% due to the synergistic conjugate effect of highly graphitized carbon and local surface plasmon resonance (LSPR) effect of Co nanoparticles.…”

Phase Change Thermal Storage Materials for Interdisciplinary Applications

“…Moreover, the encapsulation and the cross-linking procedure are complex and costly, which limit their practical applications for TES . Recently, three-dimensional cellular material (such as mesoporous silica, melamine foam, carbon foam, MOFs, and delignified wood) as structure supporting materials were gradually employed to restrain the liquid leakage issues of n -alkanes and fabricate form-stable PCM composites, which benefited from the strong interfacial tension and capillary force of the interconnected 3D vesicular structure of the framework. − …”

Fe₃O₄-Functionalized κ-Carrageenan/Melanin Hybrid Aerogel-Supported Form-Stable Phase-Change Composites with Excellent Solar/Magnetic–Thermal Conversion Efficiency and Enhanced Thermal Conductivity

“…An alternative pathway for upcycled PET@MOF-derived materials is carbonisation under elevated temperatures in an inert atmosphere with the formation of carbon-based materials. [12][13][14][15][16][17] Functional carbonised materials are nding applications as energy-related tools, such as supercapacitors, 18,19 photothermal, 20,21 and photovoltaic devices. 22,23 Carbonisation is traditionally performed by thermal annealing, which requires harsh conditions and is energyintensive.…”

Waste PET upcycling to conductive carbon-based composite through laser-assisted carbonization of UiO-66