Tailoring the physicochemical properties of solution-processed transition metal dichalcogenides via molecular approaches

Accès libre Peer reviewed | |
---|---|
Version acceptée pour publication (post-print auteur) | |
Paternité - Pas d'utilisation commerciale [CC] [BY] [NC] | |
Auteurs |
Stefano Ippolito Artur Ciesielski Paolo Samorì |
Unité de recherche du site |
Institut de Science et d'Ingénierie Supramoléculaires - ISIS - UMR7006 |
Langue |
en |
Volume |
55 |
Numéro |
61 |
Page de début |
8900 |
Page de fin |
8914 |
Date de première publication |
2019-06-27 |
ISSN |
1359-7345 |
Titre de la source (revue, livre…) |
Chemical Communications |
Résumé |
During the last five years, the scientific community has witnessed tremendous progress in solution-processed semiconducting 2D transition metal dichalcogenides (TMDs), in combination with the use of chemical approaches to finely tune their electrical Show moreDuring the last five years, the scientific community has witnessed tremendous progress in solution-processed semiconducting 2D transition metal dichalcogenides (TMDs), in combination with the use of chemical approaches to finely tune their electrical, optical, mechanical and thermal properties. Because of the strong structure–properties relationship, the adopted production methods contribute in affecting the quality and characteristics of the nanomaterials, along with the costs, scalability and yield of the process. Nevertheless, a number of (supra)molecular approaches have been developed to meticulously tailor the properties of TMDs via formation of both covalent and non-covalent bonds, where small molecules, (bio)polymers or nanoparticles interact with the basal plane and/or edges of the 2D nanosheets in a controlled fashion. In this Feature Article, we will highlight the recent advancements in the development of production strategies and molecular approaches for tailoring the properties of solution-processed TMD nanosheets. We will also discuss opportunities and challenges towards the realization of multifunctional devices and sensors based on such novel hybrid nanomaterials. Show less |
DOI | 10.1039/C9CC03845K |
Titre abrégé de la source |
Chem. Commun. |
Type de publication |
ACL |
Domaine |
Chimie/Matériaux |
Fonction |
aut |
Identifiant idREF |
151349363 109288335 |
Audience |
International |
Envoyer vers HAL |
5 |
URL | https://univoak.eu/islandora/object/islandora:80496 |