Mixing a cocktail of topology and magnetism for future electronics

Lead author Dr Semonti Bhattacharyya (Monash University School of Physics and Astronomy)

Monash review: joining topological insulators with magnetic materials for energy-efficient electronics

A new Monash review throws the spotlight on recent research in heterostructures of topological insulators and magnetic materials.

In such heterostructures, the interesting interplay of magnetism and topology can give rise to new phenomena such as quantum anomalous Hall insulators, axion insulators and skyrmions. All of these are promising building blocks for future low-power electronics.

Provided suitable candidate materials are found, there is a possibility to realise these exotic states at room temperature and without any magnetic field, hence aiding FLEET’s search for future low-energy, beyond-CMOS electronics.

Finding the right mix of topology and magnetism

A proposed topological transistor would utilise lossless paths flowing on a topological insulator’s edges.

“Our aim was to investigate promising new methods of achieving the quantum Hall effect”, says the new study’s lead author, Dr Semonti Bhattacharyya at Monash University.

The quantum Hall effect (QHE) is a topological phenomenon that allows high-speed electrons to flow at a material’s edge, which is potentially useful for future low- energy electronics and spintronics.

“However, a severe bottleneck for this technology being useful is the fact that quantum Hall effect always requires high magnetic fields, which are not possible without either high energy use or cryogenic cooling.”

When the two surfaces of topological insulators are magnetized parallel to each other, an energy gap opens on the surfaces to make them insulating, but the edges support resistanceless conducting states which can work like an electron highway.**

“There’s no point in developing ‘low energy’ electronics that consume more energy to make them work!” says Dr Bhattacharyya, who is a Research Fellow at FLEET, seeking new generation of low-energy electronics.

However, a ‘cocktail’ of topological physics and magnetism can make it possible to achieve a similar effect, the quantum anomalous Hall effect, where similar edge states appear without applying external magnetic field.

Several strategies have been followed to induce magnetism in topological insulators:

  1. by incorporating magnetic impurity,
  2. by using intrinsically magnetic topological insulators
  3. by inducing magnetism through a proximity effect in topological insulator–magnetic insulator heterostructures.

Exchange effect: One of the pathways to magnetic ordering in topological insulators is a direct exchange at the boundary of the two materials.**

“In our review, we focussed on the recent scientific research into heterostructures on the third approach,” says co-author Dr Golrokh Akhgar (FLEET/Monash). Ie, a single structure incorporating thin-film layers of topological insulators and magnetic materials adjacent to each other, allowing the topological insulator to borrow magnetic properties from its neighbour.

This approach allows researchers to tune each type of material, for example increasing the critical temperature for the magnetic material, and increasing the band gap, and decreasing the defect states, in topological materials.

“We think this approach for inducing magnetism in topological insulators is the most promising for future breakthroughs, because the magnetism and topology can be individually tuned in two different materials, thereby optimizing both to our advantage,” says co-author Matt Gebert (FLEET/Monash).

Magnetic extension: The surface state of the topological insulator extends into the neighbouring ferromagnetic insulator, interacting with magnetic moments via strong exchange interaction to produce a larger exchange bandgap and stronger insulating behaviour.**

Another important feature of this heterostructure is that the induced magnetism only depends on the magnetic moments of the nearest plane inside the magnetic material, hence the magnetic materials do not have to be ferromagnets—ferrimagnets, or antiferromagnets can also be used. This increases the number of candidate magnetic materials, allowing choice of materials with magnetism at higher temperatures, for operation closer to room temperature.

“This is an exciting new field of research,” says corresponding author Prof Michael Fuhrer, also at Monash University.

“Progress is happening extremely rapidly, and we felt it was time for a review article summarizing the recent accomplishments, and outlining a future roadmap of this field”, says Prof Fuhrer, who is director of FLEET.

The Study

This review provides all the information necessary to introduce new researchers to the field. It explains the conceptual ideas behind the mechanisms of magnetic proximity effect in topological insulators, introduces the materials systems that have been explored and the various emergent phenomenon that have been detected, and outlines a future roadmap towards increasing the temperature and innovative applications.

“We hope others will find it a timely review clarifying the important concepts of the field and recent publications,” says Semonti.

The study was chosen for the back cover of the journal**

Recent Progress in Proximity Coupling of Magnetism to Topological Insulators” was published in Advanced Materials in June 2021. (DoI: 10.1002/adma.202007795)

As well as support from the Australian Research Council through the ARC Centre of Excellence in Future Low-Energy Electronics Technologies (FLEET), the authors acknowledges an Australian Government Research Training Program Scholarship.

 Topological insulator-magnetic insulator heterostructure at FLEET

Prof Fuhrer’s team at Monash is studying assembled heterostructures of topological insulator-magnetic insulator heterostructures, in collaboration with Dr Mark Edmonds and Dr Julie Karel’s teams, as a part of research theme 1 at FLEET, an Australian Research Council Centre of Excellence.

The Centre for Future Low-Energy Electronics Technologies (FLEET) brings together over a hundred Australian and international experts, with the shared mission to develop a new generation of ultra-low energy electronics. The impetus behind such work is the increasing challenge of energy used in computation, which uses 5–8% of global electricity and is doubling every decade.

More information

** Images and top image reproduced and modified from the paper with permission from Advanced Materials (DOI 10.1002/adma.202007795).Copyright Wiley-VCH GmbH.

Co-author FLEET Associate Investigator Dr Golrokh Akhgar (Monash)

matt gebert image

Co-author FLEET PhD student Matt Gebert (Monash)

Mark Edmonds

Co-author FLEET Scientific Associate Investigator Dr Mark Edmonds

Co-author FLEET Chief Investigator Dr Julie Karel (Monash)

Michael Fuhrer

Corresponding author and Director of FLEET, Prof Michael Fuhrer (Monash)