Ti3C2T XMXene Beaded SiC Nanowires for Efficient Microwave Absorption

Yang Wang; Qiang Dou; Wei Jiang; Kai Su; Jie You; Shuang Yin; Tong Wang; Jian Yang; Quan Li

doi:10.1021/acsanm.2c01553

Ti₃C₂T _XMXene Beaded SiC Nanowires for Efficient Microwave Absorption

Yang Wang, Qiang Dou, Wei Jiang, Kai Su, Jie You, Shuang Yin, Tong Wang, Jian Yang, Quan Li

材料科学与工程学院

科研成果: 期刊稿件 › 文章 › 同行评审

39 引用（Scopus）

摘要

Flexible SiC_nwis anticipated to enable multifunctional uses of materials, such as wearable electronic components or coatings that absorb microwaves at high temperatures. By regulating the amount of raw materials, a beaded SiC nanowire (SiC_nw) comprising SiC stems (150 nm) and SiO₂beads (600 nm) was successfully manufactured in this study. In addition, the Ti₃C₂T_XMXene hybrid beaded SiC_nw(M-SiC_nw) film was produced using a straightforward suction filtration technique. The incorporation of Ti₃C₂T_XMXene nanosheets and bead flaws created abundant interfaces and increased conductivity, hence boosting the microwave absorption efficiency. At a thickness of 1.58 mm and an effective absorption bandwidth of 3.36 GHz, a minimum reflection loss value of -41.7 dB was observed. The possible absorption process of the M-SiC_nwfilm is elaborated upon. The results demonstrate that the M-SiC_nwfilm has promising future applications in membrane technology and microwave absorption.

源语言	英语
页（从-至）	9209-9222
页数	14
期刊	ACS Applied Nano Materials
卷	5
期	7
DOI	https://doi.org/10.1021/acsanm.2c01553
出版状态	已出版 - 22 7月 2022

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10.1021/acsanm.2c01553

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title = "Ti3C2T XMXene Beaded SiC Nanowires for Efficient Microwave Absorption",

abstract = "Flexible SiCnwis anticipated to enable multifunctional uses of materials, such as wearable electronic components or coatings that absorb microwaves at high temperatures. By regulating the amount of raw materials, a beaded SiC nanowire (SiCnw) comprising SiC stems (150 nm) and SiO2beads (600 nm) was successfully manufactured in this study. In addition, the Ti3C2TXMXene hybrid beaded SiCnw(M-SiCnw) film was produced using a straightforward suction filtration technique. The incorporation of Ti3C2TXMXene nanosheets and bead flaws created abundant interfaces and increased conductivity, hence boosting the microwave absorption efficiency. At a thickness of 1.58 mm and an effective absorption bandwidth of 3.36 GHz, a minimum reflection loss value of -41.7 dB was observed. The possible absorption process of the M-SiCnwfilm is elaborated upon. The results demonstrate that the M-SiCnwfilm has promising future applications in membrane technology and microwave absorption.",

keywords = "TicT MXene, beaded sic nanowire, carbothermal reduction, films, microwave absorption",

author = "Yang Wang and Qiang Dou and Wei Jiang and Kai Su and Jie You and Shuang Yin and Tong Wang and Jian Yang and Quan Li",

year = "2022",

month = jul,

day = "22",

doi = "10.1021/acsanm.2c01553",

language = "英语",

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TY - JOUR

T1 - Ti3C2T XMXene Beaded SiC Nanowires for Efficient Microwave Absorption

AU - Wang, Yang

AU - Dou, Qiang

AU - Jiang, Wei

AU - Su, Kai

AU - You, Jie

AU - Yin, Shuang

AU - Wang, Tong

AU - Yang, Jian

AU - Li, Quan

PY - 2022/7/22

Y1 - 2022/7/22

N2 - Flexible SiCnwis anticipated to enable multifunctional uses of materials, such as wearable electronic components or coatings that absorb microwaves at high temperatures. By regulating the amount of raw materials, a beaded SiC nanowire (SiCnw) comprising SiC stems (150 nm) and SiO2beads (600 nm) was successfully manufactured in this study. In addition, the Ti3C2TXMXene hybrid beaded SiCnw(M-SiCnw) film was produced using a straightforward suction filtration technique. The incorporation of Ti3C2TXMXene nanosheets and bead flaws created abundant interfaces and increased conductivity, hence boosting the microwave absorption efficiency. At a thickness of 1.58 mm and an effective absorption bandwidth of 3.36 GHz, a minimum reflection loss value of -41.7 dB was observed. The possible absorption process of the M-SiCnwfilm is elaborated upon. The results demonstrate that the M-SiCnwfilm has promising future applications in membrane technology and microwave absorption.

AB - Flexible SiCnwis anticipated to enable multifunctional uses of materials, such as wearable electronic components or coatings that absorb microwaves at high temperatures. By regulating the amount of raw materials, a beaded SiC nanowire (SiCnw) comprising SiC stems (150 nm) and SiO2beads (600 nm) was successfully manufactured in this study. In addition, the Ti3C2TXMXene hybrid beaded SiCnw(M-SiCnw) film was produced using a straightforward suction filtration technique. The incorporation of Ti3C2TXMXene nanosheets and bead flaws created abundant interfaces and increased conductivity, hence boosting the microwave absorption efficiency. At a thickness of 1.58 mm and an effective absorption bandwidth of 3.36 GHz, a minimum reflection loss value of -41.7 dB was observed. The possible absorption process of the M-SiCnwfilm is elaborated upon. The results demonstrate that the M-SiCnwfilm has promising future applications in membrane technology and microwave absorption.

KW - TicT MXene

KW - beaded sic nanowire

KW - carbothermal reduction

KW - films

KW - microwave absorption

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U2 - 10.1021/acsanm.2c01553

DO - 10.1021/acsanm.2c01553

M3 - 文章

AN - SCOPUS:85134473735

SN - 2574-0970

VL - 5

SP - 9209

EP - 9222

JO - ACS Applied Nano Materials

JF - ACS Applied Nano Materials

IS - 7

ER -

Ti3C2T XMXene Beaded SiC Nanowires for Efficient Microwave Absorption

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Ti₃C₂T _XMXene Beaded SiC Nanowires for Efficient Microwave Absorption