Bio-inspired robust and highly thermal conductive BNNS/PBO nanofiber composite films with excellent thermal stability, wear resistance, and adjustable photothermal properties

Sun, Tingting; Cao, Wenxin; Zhao, Kechen; Wang, Xiaolei; Wang, Zhuochao; Gao, Ge; Ye, Zhijie; Zhao, Kunlong; Su, Zhenhua; Dai, Bing; Zhang, Mingfu; Han, Jiecai; Zhu, Jiaqi

doi:10.1016/j.cej.2023.145916

Cited by 13 publications

(2 citation statements)

References 73 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…When a self‐healing material is damaged, it can repair the damaged area through a series of chemical or physical mechanisms to restore its original physical and chemical properties. Dong et al 172 constructed a cross‐linking network based on ionic hydrogen bonds and coordination bonds in carboxylated nitrile butadiene rubber (XNBR) to obtain a strong, damped, and heat‐conducting rubber with recyclable and self‐healing capabilities 173–176 . Due to the reversible ionic hydrogen bond and coordination bond, the prepared XNBR/G‐PPD/CuSO 4 composite has good mechanical properties, self‐healing properties, and post‐processing capabilities, as shown in Figure 26.…”

Section: Functional Thermal Conductivity Materialsmentioning

confidence: 99%

A review: From the whole process of making thermal conductive polymer, the effective method of improving thermal conductivity

Wu,

Zhang,

Yan

et al. 2024

Journal of Polymer Science

View full text Add to dashboard Cite

With the development of high power‐density electronic devices on smaller scales and emerging new energy vehicles, high thermal conductive materials have attracted more attention for better thermal management to adapt to various applications. By combining both the advantages of polymer materials and thermally conductive fillers, thermal conductive polymer composite materials are widely used in packaging and the protection of electronic devices for their mechanical robustness, high thermal conductivity, excellent insulation properties, heat resistance, and chemical resistance. In this review, first, the basic theory of heat conduction of polymer composites is discussed. Second, according to the classification of the composition of the thermal conductive polymer, the filled thermal conductive material is emphatically introduced. In this paper, the construction process of a thermal conductive network of polymer and composites is discussed from the perspective of processing. The simple construction of a thermal conductive network includes core‐shell structure, external force orientation, electrostatic spinning, electrostatic spraying, induced orientation, and vacuum‐assisted filtration. The three‐dimensional thermal conductivity network can be constructed using self‐assembly and template methods. From the above processing methods, this paper analyzes how to effectively improve thermal conductivity and achieve the goal of high thermal conductivity and excellent mechanical properties under low filling. After that, the contribution of filler and polymer modification to thermal conductivity is explained in detail. Finally, the future research direction of functionalization is prospected.

show abstract

Section: Functional Thermal Conductivity Materialsmentioning

confidence: 99%

A review: From the whole process of making thermal conductive polymer, the effective method of improving thermal conductivity

Wu,

Zhang,

Yan

et al. 2024

Journal of Polymer Science

View full text Add to dashboard Cite

show abstract

“…8,9 In the energy sector, the exceptional κ of materials can amplify heat transfer efficiency, consequently bolstering the efficacy of energy conversion and storage devices. 10,11 Graphene, as one of the most illustrious 2D materials, composed solely of a monolayer of carbon atoms, has attracted significant attention owing to its remarkable κ [12][13][14] and outstanding electronic properties. 15,16 Nevertheless, as research endeavors continue to deepen, it has come to light that numerous other 2D materials also harbor impressive κ characteristics.…”

Section: Introductionmentioning

confidence: 99%

Giant thermal conductivity and strain thermal response of nitrogen substituted diamane: a machine-learning-based prediction

Wang,

Huang,

et al. 2024

Nanoscale

Self Cite

View full text Add to dashboard Cite

show abstract

Dual‐Cooling Textile Enables Vertical Heat Dissipation and Sweat Evaporation For Thermal and Moisture Regulation

Ding,

Lin,

Cheng

et al. 2024

Adv Funct Materials

View full text Add to dashboard Cite

Personal thermal management textiles have garnered a lot of attention because they can efficiently preserve the body's thermal and moisture comfort while saving energy consumption. Nonetheless, conduction cooling‐based textile research is scarce and frequently encounters obstacles like overlooking through‐plane heat conduction, moisture management, and durability assurance. Here, a dual‐cooling textile (DCT) that combines high‐efficiency heat dissipation and sweat evaporation with a 3D thermal conductive network and Janus wetting structure is demonstrated. The DCT achieves notable in‐plane and through‐plane thermal conductivity (8.57 and 0.70 W m−1 K−1), along with practical mechanical qualities (tensile fracture strength of 65 MPa), under the influence of the 3D multistage thermal conduction network. Additionally, the DCT benefits from its Janus wetting structure, exhibiting unidirectional moisture‐wicking capability (transport index of 1081%) and fast water evaporation performance (0.34 g h−1). Rapid heat dissipation and sweat evaporation are advantageous features for the cooling of the human body in both static and dynamic situations. Compared to cotton fabric, DCT can lower the temperature by up to 3.7 °C. This strategy provides a fresh perspective on the development of advanced functional textiles for personalized cooling and energy savings in buildings.

show abstract

Bio-inspired robust and highly thermal conductive BNNS/PBO nanofiber composite films with excellent thermal stability, wear resistance, and adjustable photothermal properties

Cited by 13 publications

References 73 publications

A review: From the whole process of making thermal conductive polymer, the effective method of improving thermal conductivity

A review: From the whole process of making thermal conductive polymer, the effective method of improving thermal conductivity

Giant thermal conductivity and strain thermal response of nitrogen substituted diamane: a machine-learning-based prediction

Dual‐Cooling Textile Enables Vertical Heat Dissipation and Sweat Evaporation For Thermal and Moisture Regulation

Contact Info

Product

Resources

About