Article | REF: NM3550 V1

Magnetic nano-chains - Properties, processing and prospects

Authors: Irena MILOSEVIC, Vincent RUSSIER, Laurence MOTTE

Publication date: October 10, 2015

You do not have access to this resource.
Click here to request your free trial access!

Already subscribed? Log in!


Overview

Français

Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.

Read the article

AUTHORS

  • Irena MILOSEVIC: Doctor of Science - Associate researcher Université Paris 13, Sorbonne Paris Cité, UFR SMBH, France

  • Vincent RUSSIER: Doctor of Science - ICMPE Research Fellow, UMR 7182 CNRS and Université Paris Est, France

  • Laurence MOTTE: Doctor of Science - Professor Université Paris 13, Sorbonne Paris Cité, UFR SMBH, France

 INTRODUCTION

Hierarchical assemblies of magnetic materials have attracted a great deal of interest due to their unique structures, particular physical properties and potential technological applications. In particular, one-dimensional (1D) magnetic assemblies of nanoparticles (NPs) have been a particularly active area of research in recent years, both from a theoretical and experimental point of view. Compared with zero-dimensional NPs or so-called "single NPs", 1D NP nanochains display exacerbated magnetic properties and provide aligned and parallel surface functionalities, suitable for various technological sectors, notably in the medical and environmental fields.

The aim of this article is to carry out an in-depth bibliographical survey of the state of the art concerning one-dimensional assemblies of individual magnetic NPs. In a first section, we recall some essential characteristics of magnetic NPs and the importance of modeling involving particle systems with dipolar interactions. These interactions are at the origin of collective effects in magnetic NP assemblies, due to their long range, and help explain chain formation in certain cases. So, beyond a fundamental investigation of the various processes, a good understanding of dipolar effects can also have a predictive character. In a second section, we present the various experimental strategies that have been developed in recent years to obtain these organizations: directed dipolar self-assembly, assembly induced by a magnetic field, or synthesis assisted by the use of a "chemical mold" (or template), the chemical assembly of particles presenting two different functionalities or physical methods such as electrospinning or using microfluidic systems. Some of these strategies can be combined, notably the use of a magnetic field, which can help direct chain formation in all the strategies considered. The last part of the article presents the various applications of these nanochains, particularly in the life and environmental sciences.

You do not have access to this resource.

Exclusive to subscribers. 97% yet to be discovered!

You do not have access to this resource.
Click here to request your free trial access!

Already subscribed? Log in!


The Ultimate Scientific and Technical Reference

A Comprehensive Knowledge Base, with over 1,200 authors and 100 scientific advisors
+ More than 10,000 articles and 1,000 how-to sheets, over 800 new or updated articles every year
From design to prototyping, right through to industrialization, the reference for securing the development of your industrial projects

This article is included in

Functional materials - Bio-based materials

This offer includes:

Knowledge Base

Updated and enriched with articles validated by our scientific committees

Services

A set of exclusive tools to complement the resources

Practical Path

Operational and didactic, to guarantee the acquisition of transversal skills

Doc & Quiz

Interactive articles with quizzes, for constructive reading

Subscribe now!

Ongoing reading
Magnetic nano-chains