Flexible electronics based on one‐dimensional and two‐dimensional hybrid nanomaterials
Abstract Research on flexible or wearable electronics has been grown remarkably due to the advent of nanomaterials, such as metal nanowires, graphene, or transition metal dichalcogenides. Although each nanomaterial has mechanical and electrical characteristics that can be applied into flexible elect...
Main Authors: | , , , |
---|---|
Format: | Article |
Language: | English |
Published: |
Wiley
2020-01-01
|
Series: | InfoMat |
Subjects: | |
Online Access: | https://doi.org/10.1002/inf2.12047 |
id |
doaj-d05d6b1e1c1445429ca77ac9c1325f57 |
---|---|
record_format |
Article |
spelling |
doaj-d05d6b1e1c1445429ca77ac9c1325f572020-11-25T02:09:52ZengWileyInfoMat2567-31652020-01-0121335610.1002/inf2.12047Flexible electronics based on one‐dimensional and two‐dimensional hybrid nanomaterialsJihun Park0Jae Chul Hwang1Gon Guk Kim2Jang‐Ung Park3Department of Materials Science and Engineering Nano Science Technology Institute, Yonsei University Seoul Republic of KoreaDepartment of Materials Science and Engineering Nano Science Technology Institute, Yonsei University Seoul Republic of KoreaDepartment of Materials Science and Engineering Nano Science Technology Institute, Yonsei University Seoul Republic of KoreaDepartment of Materials Science and Engineering Nano Science Technology Institute, Yonsei University Seoul Republic of KoreaAbstract Research on flexible or wearable electronics has been grown remarkably due to the advent of nanomaterials, such as metal nanowires, graphene, or transition metal dichalcogenides. Although each nanomaterial has mechanical and electrical characteristics that can be applied into flexible electronics, the limitations of each nanomaterial are also clear. In order to overcome the limitations of these nanomaterials, research on the hybrid structures of nanomaterials has been extensively conducted. In this study, we introduce the properties of one‐dimensional nanomaterials, two‐dimensional nanomaterials, and their hybrid nanomaterials. And then, we provide information concerning various flexible electronics based on these nanomaterials.https://doi.org/10.1002/inf2.12047flexible electronicshybrid nanomaterialsone‐dimensional nanomaterialstwo‐dimensional nanomaterialswearable electronics |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Jihun Park Jae Chul Hwang Gon Guk Kim Jang‐Ung Park |
spellingShingle |
Jihun Park Jae Chul Hwang Gon Guk Kim Jang‐Ung Park Flexible electronics based on one‐dimensional and two‐dimensional hybrid nanomaterials InfoMat flexible electronics hybrid nanomaterials one‐dimensional nanomaterials two‐dimensional nanomaterials wearable electronics |
author_facet |
Jihun Park Jae Chul Hwang Gon Guk Kim Jang‐Ung Park |
author_sort |
Jihun Park |
title |
Flexible electronics based on one‐dimensional and two‐dimensional hybrid nanomaterials |
title_short |
Flexible electronics based on one‐dimensional and two‐dimensional hybrid nanomaterials |
title_full |
Flexible electronics based on one‐dimensional and two‐dimensional hybrid nanomaterials |
title_fullStr |
Flexible electronics based on one‐dimensional and two‐dimensional hybrid nanomaterials |
title_full_unstemmed |
Flexible electronics based on one‐dimensional and two‐dimensional hybrid nanomaterials |
title_sort |
flexible electronics based on one‐dimensional and two‐dimensional hybrid nanomaterials |
publisher |
Wiley |
series |
InfoMat |
issn |
2567-3165 |
publishDate |
2020-01-01 |
description |
Abstract Research on flexible or wearable electronics has been grown remarkably due to the advent of nanomaterials, such as metal nanowires, graphene, or transition metal dichalcogenides. Although each nanomaterial has mechanical and electrical characteristics that can be applied into flexible electronics, the limitations of each nanomaterial are also clear. In order to overcome the limitations of these nanomaterials, research on the hybrid structures of nanomaterials has been extensively conducted. In this study, we introduce the properties of one‐dimensional nanomaterials, two‐dimensional nanomaterials, and their hybrid nanomaterials. And then, we provide information concerning various flexible electronics based on these nanomaterials. |
topic |
flexible electronics hybrid nanomaterials one‐dimensional nanomaterials two‐dimensional nanomaterials wearable electronics |
url |
https://doi.org/10.1002/inf2.12047 |
work_keys_str_mv |
AT jihunpark flexibleelectronicsbasedononedimensionalandtwodimensionalhybridnanomaterials AT jaechulhwang flexibleelectronicsbasedononedimensionalandtwodimensionalhybridnanomaterials AT gongukkim flexibleelectronicsbasedononedimensionalandtwodimensionalhybridnanomaterials AT jangungpark flexibleelectronicsbasedononedimensionalandtwodimensionalhybridnanomaterials |
_version_ |
1724922069291892736 |