# Single-crystalline nanoribbon network field effect transistors from arbitrary two-dimensional materials

https://mdr.nims.go.jp/datasets/23d5a1ba-6968-41fc-b77c-9b21305d3556

## File

- [s41699-022-00356-y.pdf](https://mdr.nims.go.jp/filesets/f3590cc3-53f2-41bf-b715-60424ad5389d/download) ([Detail](https://mdr.nims.go.jp/filesets/f3590cc3-53f2-41bf-b715-60424ad5389d.md))

## Id

23d5a1ba-6968-41fc-b77c-9b21305d3556

## Local identifier



## Visibility

open_to_public

## State

published

## Created at

2025-02-27T04:52:35.759679Z

## Updated at

2025-02-27T23:30:55.532327Z

## Published at

2025-02-27T23:30:55.622384Z

## Doi



## First published url

https://doi.org/10.1038/s41699-022-00356-y

## Date published

2022-10-31

## Recorded date published



## Resource type

journal_article

## Manuscript type

vor

## Collection



## Title

- title: Single-crystalline nanoribbon network field effect transistors from arbitrary
    two-dimensional materials
  title_type: original
  lang: en

## Description

- description: The last decade has seen a flurry of studies related to graphene nanoribbons
    due to their potential applications in the quantum realm. However, little experimental
    work has been done towards nanoribbons of other 2D materials due to the absence
    of synthesis routes. Furthermore, 2D material nanoribbon fabrication methods need
    to be scalable, while maintaining high crystallinity, sufficient yield, narrow
    size dis- tribution, and straight-forward device integrability.We apply a universal
    approach to synthesize high-quality networks of nanoribbons from arbitrary 2D
    materials. The wide applicability of this technique is demonstrated by fabricating
    MoS2, WS2, WSe2, and graphene nanoribbon field effect transistors that inherently
    do not suffer from in- terconnection resistances and network percolation issues.
    By relying on self-assembled and self-aligned organic nanostructures as masks,
    we demonstrate the possibility of controlling the predominant crystallographic
    direction of the nanoribbon's edges. Obtained nanoribbons demonstrate excellent
    optical and electronic properties inherent to their single crystalline structure.
    Electrical characterization shows record mobil- ities and very high ON currents
    for various TMDCs despite extreme width scaling (< 20 nm). Lastly, we explore
    decoration of nanoribbon edges with plasmonic particles paving the way towards
    the development of nanoribbon based plasmonic sensing and opto-electronic devices.
  description_type: abstract
  lang: und

## Creator

- name: Muhammad Awais Aslam
  role: author
- name: Tuan Hoang Tran
  role: author
- name: Antonio Supina
  role: author
- name: Olivier Siri
  role: author
- name: Vincent Meunier
  role: author
- name: Kenji Watanabe
  role: author
  orcid: https://orcid.org/0000-0003-3701-8119
  organization: National Institute for Materials Science
  ror: https://ror.org/026v1ze26
- name: Takashi Taniguchi
  role: author
  orcid: https://orcid.org/0000-0002-1467-3105
  organization: National Institute for Materials Science
  ror: https://ror.org/026v1ze26
- name: Marko Kralj
  role: author
- name: Christian Teichert
  role: author
- name: Evgeniya Sheremet
  role: author
- name: Raul D. Rodriguez
  role: author
- name: Aleksandar Matković
  role: author

## Contact agent



## Publisher

organization: Springer Science and Business Media LLC

## Managing organization



## Keyword

- subject: Graphene nanoribbons
  schema: not_defined
- subject: quantum realm
  schema: not_defined
- subject: opto-electronic devices
  schema: not_defined

## Rights

- identifier: https://creativecommons.org/licenses/by/4.0/

## Other identifier(s)



## Data origin

- data_origin_type: other

## Embargo



## Journal

- title: npj 2D Materials and Applications
  issn: '23977132'
  volume: '6'
  issue: '1'
  article_number: '76'

## Conference



## Related item



## Funding



## Instrument



## Instrument operator



## Instrument managing organization



## Measurement method



## Specimen



## Chemical composition



## Structure for specimen



## Structural feature for specimen



## Specific property for specimen



## Process for specimen treatment



## Computational method



## Energy level/transition state



## Software



## Custom property



## Fileset

- id: f3590cc3-53f2-41bf-b715-60424ad5389d
  filename: s41699-022-00356-y.pdf
  content_type: application/pdf
  size: 3809432
  md5: 9464f2a9ff706566ff39436a10556893

## Thumbnail

fileset_id: f3590cc3-53f2-41bf-b715-60424ad5389d
filename: s41699-022-00356-y.pdf