Selective coding dielectric genes based on proton tailoring to improve microwave absorption of MOFs

Jiaqi Tao; Linling Xu; Haoshan Jin; Yansong Gu; Jintang Zhou; Zhengjun Yao; Xuewei Tao; Ping Chen; Wang Dinghui Wang; Zhong Li; Hongjing Wu

doi:10.1016/j.apmate.2022.100091

Selective coding dielectric genes based on proton tailoring to improve microwave absorption of MOFs

Jiaqi Tao
, Linling Xu
, Haoshan Jin
, Yansong Gu
, Jintang Zhou
, Zhengjun Yao
, Xuewei Tao
, Ping Chen
, Wang Dinghui Wang
, Zhong Li
, Hongjing Wu

物理科学与技术学院

Nanjing University of Aeronautics and Astronautics
Nanjing Institute of Technology
Nanjing University
Southwest Jiaotong University
Royal Melbourne Institute of Technology University

科研成果: 期刊稿件 › 文章 › 同行评审

130 引用（Scopus）

摘要

Regulating dielectric genes of hollow metal-organic frameworks is a milestone project for microwave absorption (MA). However, there is still a bottleneck in deciphering the contribution of various dielectric genes, making it hard to expand the MA potential from selective encoding gene sequences. Herein, a custom-made proton tailoring strategy is used to build a controllable cavity, and meticulously designed thermodynamic regulation promotes the rearrangement of carbon atoms from disorder to order, thus enhancing the characteristics of charge transfer. Meanwhile, the defect-configuration transformation from heteroatom to vacancy and geometric configuration of hollow structure increase the polarization-related dielectric genes. Therefore, MA performance is enhanced towards broadband absorption (6.6 GHz, 1.78 mm) and high-efficiency loss (−62.5 dB), making samples suitable for complex open electromagnetic environments. This work realizes the tradeoff between dielectric gene sequences and provides a profound insight into the functions and sources of various microwave loss mechanisms.

源语言	英语
文章编号	100091
期刊	Advanced Powder Materials
卷	2
期	1
DOI	https://doi.org/10.1016/j.apmate.2022.100091
出版状态	已出版 - 1月 2023

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title = "Selective coding dielectric genes based on proton tailoring to improve microwave absorption of MOFs",

abstract = "Regulating dielectric genes of hollow metal-organic frameworks is a milestone project for microwave absorption (MA). However, there is still a bottleneck in deciphering the contribution of various dielectric genes, making it hard to expand the MA potential from selective encoding gene sequences. Herein, a custom-made proton tailoring strategy is used to build a controllable cavity, and meticulously designed thermodynamic regulation promotes the rearrangement of carbon atoms from disorder to order, thus enhancing the characteristics of charge transfer. Meanwhile, the defect-configuration transformation from heteroatom to vacancy and geometric configuration of hollow structure increase the polarization-related dielectric genes. Therefore, MA performance is enhanced towards broadband absorption (6.6 GHz, 1.78 mm) and high-efficiency loss (−62.5 dB), making samples suitable for complex open electromagnetic environments. This work realizes the tradeoff between dielectric gene sequences and provides a profound insight into the functions and sources of various microwave loss mechanisms.",

keywords = "Dielectric genes, Hollow structure, MOFs, Microwave absorption, N-doped C/Co-QDs, Proton tailoring",

author = "Jiaqi Tao and Linling Xu and Haoshan Jin and Yansong Gu and Jintang Zhou and Zhengjun Yao and Xuewei Tao and Ping Chen and \{Dinghui Wang\}, Wang and Zhong Li and Hongjing Wu",

note = "Publisher Copyright: {\textcopyright} 2022 Central South University.",

year = "2023",

month = jan,

doi = "10.1016/j.apmate.2022.100091",

language = "英语",

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TY - JOUR

T1 - Selective coding dielectric genes based on proton tailoring to improve microwave absorption of MOFs

AU - Tao, Jiaqi

AU - Xu, Linling

AU - Jin, Haoshan

AU - Gu, Yansong

AU - Zhou, Jintang

AU - Yao, Zhengjun

AU - Tao, Xuewei

AU - Chen, Ping

AU - Dinghui Wang, Wang

AU - Li, Zhong

AU - Wu, Hongjing

PY - 2023/1

Y1 - 2023/1

N2 - Regulating dielectric genes of hollow metal-organic frameworks is a milestone project for microwave absorption (MA). However, there is still a bottleneck in deciphering the contribution of various dielectric genes, making it hard to expand the MA potential from selective encoding gene sequences. Herein, a custom-made proton tailoring strategy is used to build a controllable cavity, and meticulously designed thermodynamic regulation promotes the rearrangement of carbon atoms from disorder to order, thus enhancing the characteristics of charge transfer. Meanwhile, the defect-configuration transformation from heteroatom to vacancy and geometric configuration of hollow structure increase the polarization-related dielectric genes. Therefore, MA performance is enhanced towards broadband absorption (6.6 GHz, 1.78 mm) and high-efficiency loss (−62.5 dB), making samples suitable for complex open electromagnetic environments. This work realizes the tradeoff between dielectric gene sequences and provides a profound insight into the functions and sources of various microwave loss mechanisms.

AB - Regulating dielectric genes of hollow metal-organic frameworks is a milestone project for microwave absorption (MA). However, there is still a bottleneck in deciphering the contribution of various dielectric genes, making it hard to expand the MA potential from selective encoding gene sequences. Herein, a custom-made proton tailoring strategy is used to build a controllable cavity, and meticulously designed thermodynamic regulation promotes the rearrangement of carbon atoms from disorder to order, thus enhancing the characteristics of charge transfer. Meanwhile, the defect-configuration transformation from heteroatom to vacancy and geometric configuration of hollow structure increase the polarization-related dielectric genes. Therefore, MA performance is enhanced towards broadband absorption (6.6 GHz, 1.78 mm) and high-efficiency loss (−62.5 dB), making samples suitable for complex open electromagnetic environments. This work realizes the tradeoff between dielectric gene sequences and provides a profound insight into the functions and sources of various microwave loss mechanisms.

KW - Dielectric genes

KW - Hollow structure

KW - MOFs

KW - Microwave absorption

KW - N-doped C/Co-QDs

KW - Proton tailoring

UR - https://www.scopus.com/pages/publications/85141114917

U2 - 10.1016/j.apmate.2022.100091

DO - 10.1016/j.apmate.2022.100091

M3 - 文章

AN - SCOPUS:85141114917

SN - 2772-834X

VL - 2

JO - Advanced Powder Materials

JF - Advanced Powder Materials

IS - 1

M1 - 100091

ER -

Selective coding dielectric genes based on proton tailoring to improve microwave absorption of MOFs

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