Skyrmionics: From Magnetic Excitations to Functioning Low-Energy Devices
Lead Research Organisation:
Durham University
Department Name: Physics
Abstract
Tony Skyrme proposed that under special circumstances it is possible to stabilize vortex-like whirls in fields to produce topologically stable objects. This idea, effectively of creating a new type of fundamental particle, has been realised with the recent discovery of skyrmions in magnetic materials. The confirmation of the existence of skyrmions in chiral magnets and of their self-organization into a skyrmion lattice has made skyrmion physics arguably the hottest topic in magnetism research at the moment. Skyrmions are excitations of matter whose occurrence and collective properties are mysterious, but which hold promise for advancing our basic understanding of matter and also for technological deployment as highly efficient memory elements. Following the discovery of skyrmions in a variety of materials, several urgent questions remain which are holding back the field: what are the general properties of the phase transitions that lead to the skyrmion lattice phase, the nature of its structure, excitations and stability and how might we exploit the unique magnetic properties of this matter in future devices? These questions have only recently begun to be addressed by several large international consortia and are far from being resolved. For the UK to contend in this highly competitive field a major project is required that brings together UK experts in materials synthesis and state-of-the-art theoretical and experimental techniques. We propose the first funded UK national programme to investigate skyrmions, skyrmion lattices and skyrmionic devices. Our systematic approach, combining experts from different fields is aimed at answering basic questions about the status of magnetic skyrmions and working with industrial partners to develop technological applications founded on this physics.
Planned Impact
{Knowledge impact: scientific}
Our research will generate immediate and significant cross-disciplinary impact that will benefit physicists, chemists and materials scientists studying magnetism, the wider community of many-body quantum mechanics and topological physics, and the areas of technological applications of magnetism and materials simulation. We are especially excited that this will impact across disciplines, enabling us to extend our research to those in the areas of materials discovery, thin film growth, topological physics and technological development.
{Knowledge impact: technical}
We will work towards the design of a skymionic device that will open up prospects for ultra-low power information and storage technologies. This will address the ever-increasing demands for processing and storing extraordinarily large amounts of data. Current spintronic devices work by reversing the magnetic ordering within micron-sized ferromagnetic domains. Skyrmions are of size 10 - 100 nm and are remarkably mobile. They can be created, transported and manipulated by electric and magnetic fields. Electrical current densities of 10^6 Am^-2 can cause skyrmion motion, which compares with 10^11 Am^-2 required to move ferromagnetic domains. Skyrmions therefore represent a potential route to high-density, low-energy magnetic storage and the smallest micromagnetic configuration objects for novel ultra low-power magnetoelectrical devices. We aim to develop skyrmionic materials towards the point of deployment in device applications in collaboration with our industrial partners. Also key to our proposal is the development and use of state-of-the-art measurement technologies and theoretical techniques. Working closely with industry we will align our scientific programme with the engineering and commercial realities of modern-day information technologies.
{Economic impact and IP}
The potential economic impact of skyrmionics is enormous. Ultra high density magnetic storage and low energy magnetic sensors could result from our research. IP generated in fields such as magnetic devices and information processing/computing will be identified and protected with the assistance of the knowledge transfer services from the institutions involved.
{People and training}
A project of this scale which involves significant staff time provides an opportunity to exploit a powerful and varied platform for training. This will centre around the cohort of PDRAs, who will be trained in a variety of state-of-the-art experimental and theoretical techniques including crystal and film growth, physical characterization and experimentation, theoretical modelling and industrial work. Each will benefit from the diverse range of techniques we will employ as part of the project and also from the range of working environments involved. Senior PDRAs will play a role in mentoring junior colleagues and supervising the work of PhD students. The PDRAs will manage and organise internal project meetings and seminars along with writing an electronic project newsletter and blog on the project website.
{Outreach}
Topological objects are not limited to skyrmions, but include domain walls (used in memory applications), vortices (used in superconducting devices) and monopoles (thought to exist in the early Universe). These are of increasing importance in modern science and technology but are relatively unexplored in the classroom, despite the fact that they are most easily explained with pictures rather than sophisticated mathematics. We will initiate an outreach effort as part of this project combining workshops for Key Stage 3 students along with an outreach website aimed at the established web-based community of popular science enthusiasts. Our outreach project aims to introduce the ideas of topological physics to a broad audience and stress its great potential for applications in future technologies.
Our research will generate immediate and significant cross-disciplinary impact that will benefit physicists, chemists and materials scientists studying magnetism, the wider community of many-body quantum mechanics and topological physics, and the areas of technological applications of magnetism and materials simulation. We are especially excited that this will impact across disciplines, enabling us to extend our research to those in the areas of materials discovery, thin film growth, topological physics and technological development.
{Knowledge impact: technical}
We will work towards the design of a skymionic device that will open up prospects for ultra-low power information and storage technologies. This will address the ever-increasing demands for processing and storing extraordinarily large amounts of data. Current spintronic devices work by reversing the magnetic ordering within micron-sized ferromagnetic domains. Skyrmions are of size 10 - 100 nm and are remarkably mobile. They can be created, transported and manipulated by electric and magnetic fields. Electrical current densities of 10^6 Am^-2 can cause skyrmion motion, which compares with 10^11 Am^-2 required to move ferromagnetic domains. Skyrmions therefore represent a potential route to high-density, low-energy magnetic storage and the smallest micromagnetic configuration objects for novel ultra low-power magnetoelectrical devices. We aim to develop skyrmionic materials towards the point of deployment in device applications in collaboration with our industrial partners. Also key to our proposal is the development and use of state-of-the-art measurement technologies and theoretical techniques. Working closely with industry we will align our scientific programme with the engineering and commercial realities of modern-day information technologies.
{Economic impact and IP}
The potential economic impact of skyrmionics is enormous. Ultra high density magnetic storage and low energy magnetic sensors could result from our research. IP generated in fields such as magnetic devices and information processing/computing will be identified and protected with the assistance of the knowledge transfer services from the institutions involved.
{People and training}
A project of this scale which involves significant staff time provides an opportunity to exploit a powerful and varied platform for training. This will centre around the cohort of PDRAs, who will be trained in a variety of state-of-the-art experimental and theoretical techniques including crystal and film growth, physical characterization and experimentation, theoretical modelling and industrial work. Each will benefit from the diverse range of techniques we will employ as part of the project and also from the range of working environments involved. Senior PDRAs will play a role in mentoring junior colleagues and supervising the work of PhD students. The PDRAs will manage and organise internal project meetings and seminars along with writing an electronic project newsletter and blog on the project website.
{Outreach}
Topological objects are not limited to skyrmions, but include domain walls (used in memory applications), vortices (used in superconducting devices) and monopoles (thought to exist in the early Universe). These are of increasing importance in modern science and technology but are relatively unexplored in the classroom, despite the fact that they are most easily explained with pictures rather than sophisticated mathematics. We will initiate an outreach effort as part of this project combining workshops for Key Stage 3 students along with an outreach website aimed at the established web-based community of popular science enthusiasts. Our outreach project aims to introduce the ideas of topological physics to a broad audience and stress its great potential for applications in future technologies.
Organisations
- Durham University (Lead Research Organisation)
- RIKEN (Collaboration)
- Toshiba (United Kingdom) (Project Partner)
- National Synchrotron Radiation Research Center (Project Partner)
- Institut Laue-Langevin (Project Partner)
- CARDIFF UNIVERSITY (Project Partner)
- Technical University of Munich (Project Partner)
- PSI (Switzerland) (Project Partner)
- Samsung (United Kingdom) (Project Partner)
- Dalhousie University (Project Partner)
- Seagate (United States) (Project Partner)
- European Synchrotron Radiation Facility (Project Partner)
- IBM (United States) (Project Partner)
- Diamond Light Source (Project Partner)
- Tamkang University (Project Partner)
- Science and Technology Facilities Council (Project Partner)
- University of Parma (Project Partner)
Publications
Mayoh D
(2021)
Effects of Fe Deficiency and Co Substitution in Polycrystalline and Single Crystals of Fe 3 GeTe 2
in Crystal Growth & Design
Mayoh D
(2021)
Anisotropic superconductivity and unusually robust electronic critical field in single crystal La 7 Ir 3
in Physical Review Materials
Mayoh D
(2022)
Giant topological and planar Hall effect in Cr 1 / 3 NbS 2
in Physical Review Research
Maskery I
(2016)
Bulk crystal growth and surface preparation of NiSb, MnSb, and NiMnSb
in Journal of Vacuum Science & Technology B, Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phenomena
Manson J
(2020)
Enhancing easy-plane anisotropy in bespoke Ni(II) quantum magnets
in Polyhedron
Léger M
(2021)
Field-temperature phase diagram of the enigmatic Nd 2 ( Zr 1 - x Ti x ) 2 O 7 pyrochlore magnets
in Physical Review B
Loudon JC
(2019)
Do Images of Biskyrmions Show Type-II Bubbles?
in Advanced materials (Deerfield Beach, Fla.)
Loudon J
(2018)
Direct observation of attractive skyrmions and skyrmion clusters in the cubic helimagnet Cu 2 OSeO 3
in Physical Review B
Liu X
(2023)
Wafer-Scale Epitaxial Growth of the Thickness-Controllable Van Der Waals Ferromagnet CrTe 2 for Reliable Magnetic Memory Applications
in Advanced Functional Materials
Liu J
(2019)
Unconventional Field-Induced Spin Gap in an S=1/2 Chiral Staggered Chain.
in Physical review letters
Liu J
(2023)
Magnetic Topological Insulator Heterostructures: A Review.
in Advanced materials (Deerfield Beach, Fla.)
Liu J
(2020)
Kerr effect anomaly in magnetic topological insulator superlattices.
in Nanotechnology
Liu J
(2019)
A low-temperature Kerr effect microscope for the simultaneous magneto-optic and magneto-transport study of magnetic topological insulators
in Measurement Science and Technology
Liu J
(2020)
Exchange Bias in Magnetic Topological Insulator Superlattices.
in Nano letters
Liu HJ
(2016)
A Metal-Insulator Transition of the Buried MnO2 Monolayer in Complex Oxide Heterostructure.
in Advanced materials (Deerfield Beach, Fla.)
Littlehales M
(2022)
Enhanced skyrmion metastability under applied strain in FeGe
in Physical Review B
Littlehales M
(2022)
Enhanced skyrmion metastability under applied strain in FeGe
Li X
(2019)
Oriented 3D Magnetic Biskyrmions in MnNiGa Bulk Crystals.
in Advanced materials (Deerfield Beach, Fla.)
Li W
(2019)
Anatomy of Skyrmionic Textures in Magnetic Multilayers.
in Advanced materials (Deerfield Beach, Fla.)
Lewis GR
(2023)
Cones and spirals: Multi-axis acquisition for scalar and vector electron tomography.
in Ultramicroscopy
Lewis G
(2020)
Magnetic Vortex States in Toroidal Iron Oxide Nanoparticles: Combining Micromagnetics with Tomography
in Nano Letters
Leutner K
(2023)
Skyrmion automotion and readout in confined counter-sensor device geometries
in Physical Review Applied
Leonov AO
(2016)
Three-dimensional chiral skyrmions with attractive interparticle interactions.
in Journal of physics. Condensed matter : an Institute of Physics journal
Description | Members of the Skyrmion project have discovered a method of measuring the topological charge, or winding number, of topological objects such as Skyrmions using polarised x-rays |
Exploitation Route | A new way to experimentally determine the topological winding number of a system has been discovered The elegant mathematical concept of topology generally describes a system's protected symmetry, which cannot be captured by the well-established symmetry-breaking theories. Driven by the enormous success of topological insulators and magnetic skyrmions, topologically protected materials are at the centre of attention. However, until now, the experimental determination of topological properties of materials was very indirect, and heavily relying on theoretical modelling in support of the experimental data. In a recent article in Nature Communications, scientists report on a new general physical principle that allows direct access to the topological property of materials. |
Sectors | Digital/Communication/Information Technologies (including Software),Electronics,Energy |
URL | http://www.diamond.ac.uk/Science/Research/Highlights/2017/topological-knots.html |
Description | Participation in Science Festival Durham for School children Participation in Celebrate Science festival for children and families Saturday Morning Science Lecture for Children and families |
Sector | Digital/Communication/Information Technologies (including Software),Education,Electronics,Energy |
Impact Types | Cultural,Societal,Economic |
Description | JSPS Summer scholarship for PhD student Max Birch to undertake research in Japan |
Organisation | RIKEN |
Department | Institute of Physical and Chemical Research (RIKEN) |
Country | Japan |
Sector | Public |
PI Contribution | PhD student Max Birch applied to JSPS and was awarded a Summer fellowship which covered return travel to Japan and living expenses for 10 weeks in 2018. During his time in Japan he undertook research on skyrmions which led to joint publications. |
Collaborator Contribution | Supervision of PhD student, cost of equipment and consumables used. Travel by RIKEN staff to UK for research meetings. |
Impact | Research papers written. Details supplied under outputs. |
Start Year | 2017 |
Description | JSPS Summer scholarship for PhD student Sam Moody |
Organisation | RIKEN |
Country | Japan |
Sector | Public |
PI Contribution | Student preparing research programme, producing samples to take to Japan. Joint research undertaken with RIKEN. |
Collaborator Contribution | Supervision of PhD student for 10 week period. Joint research undertaken with Durham. |
Impact | The visit in Summer 2020 was delayed because of Covid until 2021. The visit happened August 2022 - November 2022. |
Start Year | 2019 |
Title | ubermag/micromagnetictests: Universal micromagnetic tests for different calculators. |
Description | Micromagnetic tests for Ubermag calculators |
Type Of Technology | Software |
Year Produced | 2020 |
Open Source License? | Yes |
URL | https://zenodo.org/record/3707736 |
Title | ubermag/micromagnetictests: Universal micromagnetic tests for different calculators. |
Description | Micromagnetic tests for Ubermag calculators |
Type Of Technology | Software |
Year Produced | 2020 |
Open Source License? | Yes |
URL | https://zenodo.org/record/3707737 |