Table 1 Summary of the application of radiative cooling in flexible electronics depending on methods, materials, \({\bar{R}}_{{solar}}\), \({\bar{\varepsilon }}_{{rad}}\), applications
Methods | Materials | \({\bar{{\boldsymbol{R}}}}_{{\boldsymbol{solar}}}\) | \({\bar{{\boldsymbol{\varepsilon }}}}_{{\boldsymbol{rad}}}\) | Applications |
|---|---|---|---|---|
Solvent phase separation technique | P(VdF-HFP),SiO2,BaSO4 | 96% | 97% | Thermoelectric52 |
PMMA, SiO2,c-PI | <15% | 94.6% | flexible electronic displays33 | |
P(VdF-HFP),SiO2,h-BN | 94.9% | 91.2% | Electronic devices41 | |
Electrospinning | P(VdF-HFP),SiO2 | 83% | 95% | Triboelectric nanogenerators67 |
PU,Al2O3,TF | 94.8% | 95% | personal thermal management134 | |
P(VdF-HFP) | 96% | 96% | Stress monitoring electronics32 | |
Weaving | SEBS, Al2O3 | 90% | 97% | Epidermal electronics97 |
PE, SiO2 | 90.2% | 86% | Smart Textiles100 | |
Electrospinning and weaving | SEBS,PTFE | 92.4% | 94.5% | Epidermal electronics42 |
PTFE,PLA,TiO2 | 92.4% | 94.5% | Personal thermal management27 | |
Template Method | PDMS | <5% | 100% | Solar cells86 |
