Three-Dimensional Printing to Fabricate Graphene-Modified Polyolefin Elastomer Flexible Composites with Tailorable Porous Structures for Electromagnetic Interference Shielding and Thermal Management Application

Lv, Qinniu; Peng, Zilin; Meng, Yan; Pei, Haoran; Chen, Yinghong; Ivanov, Evgeni; Kotsilkova, Rumiana

doi:10.1021/acs.iecr.2c03086

Cited by 22 publications

(16 citation statements)

References 64 publications

(114 reference statements)

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“…This work has enriched the material of 3D-printed electromagnetic shields to explore the development of customized electromagnetic shielding components. Chen's team 174 combined ultrasonic dispersion and 3D printing techniques to prepare polyolefin elastomer (POE)/GNPs nanocomposites. They firstly improved the solvent and dispersant based on the previous work.…”

Section: D-printed Electromagnetic Shieldsmentioning

confidence: 99%

Advancements in 3D-printed architectures for electromagnetic interference shields

Zhang,

Wang,

Xie

et al. 2024

J. Mater. Chem. A

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Section: D-printed Electromagnetic Shieldsmentioning

confidence: 99%

Advancements in 3D-printed architectures for electromagnetic interference shields

Zhang,

Wang,

Xie

et al. 2024

J. Mater. Chem. A

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“…Polymer foaming has been proven an effective method for fabricating lightweight EMI shielding polymer composites 224–233 . For example, Cai et al 233 prepared closed‐cell foams with an adjustable EMI shielding response by incorporating temperature‐sensitive microspheres (TSM) into a mixture of PDMS and CNTs.…”

Section: Progress In Structural Design Of Composites For Emi Shieldingmentioning

confidence: 99%

“…Polymer foaming has been proven an effective method for fabricating lightweight EMI shielding polymer composites. [224][225][226][227][228][229][230][231][232][233] For example, Cai et al 233 prepared closed-cell foams with an adjustable EMI shielding response by incorporating temperature-sensitive microspheres (TSM) into a mixture of PDMS and CNTs. The EMI shielding performance under varied temperatures and compressive strains of PDMS/TSM/CNTs composites was investigated, and the corresponding regulatory mechanism on EMI shielding was explored.…”

Section: Polymer Foamingmentioning

confidence: 99%

Recent advances in structural design of conductive polymer composites for electromagnetic interference shielding

Zheng,

Wang,

Zhu

et al. 2023

Polymer Composites

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The proliferation of electronic devices and wireless communication in our daily lives has led to a significant increase in electromagnetic pollution. This issue poses a serious threat to the proper functioning of electronic equipment as well as human health. Therefore, the investigation of materials with superior electromagnetic interference (EMI) shielding capabilities has garnered growing interest. In this paper, the mechanisms of EMI shielding were first introduced briefly. It was noted that the development of advanced EMI shielding materials involved adhering to principles such as minimizing reflection loss, enhancing absorption loss, and incorporating multiple internal reflections. The construction and shielding properties of traditional EMI shielding materials were introduced. Unlike metal materials with high densities and reflection loss, lightweight conductive polymer composites (CPCs) have been the most promising EMI shielding materials. Meanwhile, carbon‐based nanofillers such as carbon nanotubes and graphene nanosheets, along with two‐dimensional transition metal carbonitrides MXenes Ti3C2Tx, have emerged as the most promising and versatile conductive nanofillers for CPCs. The EMI shielding performance and loss mechanism of CPCs with homogeneous structure, segregated structure, laminated structure, and porous structure were introduced in detail. It was noted that the EMI shielding performance could be significantly improved by incorporating multiple structures into the same CPCs, such as a rational combination of segregated and porous structures. Finally, the challenges and development trends of CPCs for EMI shielding applications were discussed.Highlights Mechanisms of EMI shielding were introduced from aspect of energy dissipation. Structure–property of traditional EMI shielding materials was described. EMI shielding performance of CPCs with different structures was summarized. Future challenges and growing trends of CPCs for EMI shielding were discussed. Absorption‐dominated loss and multiple structure design were emphasized.

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“…Polyethylene (PE) is a commonly used plastic material with a wide range of applications. − The research studies of PE have also received extensive attention for its synthesis, modification, − application, − degradation, , etc. Foaming technology has been widely applied in PE products, such as injection foaming and rotational foaming. − The foaming behavior directly affects the performance of the PE foaming products.…”

Section: Introductionmentioning

confidence: 99%

Significantly Tunable Foaming Behavior of Blowing Agent for the Polyethylene Foam Resin with a Unique Designed Blowing Agent System

Chen,

Huang

2024

ACS Omega

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The chemical blowing agent plays a crucial role in enhancing the performance of the polyethylene (PE) foaming resin during the rotational foaming process. Previously, the conventional blowing agent of the PE resin commonly used pure azodicarbonamide (AZ). It had the unavoidable drawbacks of releasing NH 3 and exhibiting strong reactions during the rotational foaming process. Meantime, pure AZ had a relatively high decomposition temperature, resulting in a sharp foaming process. To address the above issues, this work developed a uniquely designed blowing agent system. In this study, a novel blowing agent for the PE resin was successfully synthesized by a one-pot method. This blowing agent consisted of an activator and AZ, which exhibited a lower decomposition temperature and a milder decomposition rate than AZ. The activator was constituted of small-sized ammonium dihydrogen phosphate on the AZ surface, which could be decomposed properly and deliver phosphoric acid and H 2 O during the foaming process. Then, AZ reacted with H 2 O under phosphoric acid catalysis. Also, this reaction generated CO 2 emission while reducing the emission of NH 3 through recombination with phosphoric acid. Moreover, phosphoric acid catalysis caused a decrease in the AZ decomposition temperature. Meantime, the thermal coupling appeared during the foaming process, which could further reduce the decomposition rate. Consequently, the small activator played a key role in regulating cell formation and diffusion. Compared to AZ, the novel blowing agent system significantly reduced the cell diameter of the PE foam resin and enhanced its flexural modulus by 50%. Furthermore, the novel blowing agent facilitated better demolding performance and improved the surface morphology of the PE foam product. This research provides significant foaming behavior regulation for the PE resin during industrial applications.

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Three-Dimensional Printing to Fabricate Graphene-Modified Polyolefin Elastomer Flexible Composites with Tailorable Porous Structures for Electromagnetic Interference Shielding and Thermal Management Application

Cited by 22 publications

References 64 publications

Advancements in 3D-printed architectures for electromagnetic interference shields

Advancements in 3D-printed architectures for electromagnetic interference shields

Recent advances in structural design of conductive polymer composites for electromagnetic interference shielding

Significantly Tunable Foaming Behavior of Blowing Agent for the Polyethylene Foam Resin with a Unique Designed Blowing Agent System

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