Controlling magnetic materials on the nanoscale plays a key role in our society, having enabled for instance the development of thin film hard disk media, which has brought our ability to store and share information to unprecedented levels. Today, beyond hard disks, nanomagnetism offers key advantages over alternative technological approaches, including intrinsic non-volatility and very low power consumption, with devices such as Magnetic Random-Access Memory (MRAM) close to largescale production.

Within this field, most magnetic nanostructures are intrinsically 2D in nature, in part due to continued exploitation of sophisticated (2D) thin film processing techniques. While planar geometries have given rise to a multitude of functionalities and devices, it is now becoming apparent that to address the fundamental bottlenecks faced by current technologies, a paradigm shift is required.

Demonstration of magnetism from 2D to 3D

A radically-new approach to overcome current fundamental limits, consisting of moving to more complex, hierarchical systems that exploit three-dimensional (3D) magnetic configurations and geometries. 3D nanoscale magnetic phenomena broadly open up a range of strategies for enhancing computation, sensing and communication technologies. For example, the increased complexity within 3D interacting magnetic networks offers the opportunity for increased complexity in neuromorphic computation analogues, while the massive degeneracy in reconfigurable 3D artificial magnetic crystals offers new prospects in spin-wave logic and communication devices.

Beyond a device perspective, wholly new physics are predicted to emerge in 3D. This includes new magneto-chiral effects in curved geometries, novel spin configurations, ultra-fast motion of spin textures, novel interplay mechanisms between spatial and spin topologies, and strong coupling between magnetism and temperature or strain, to cite a few.

Our group is developing a cutting-edge research program on 3D nanomagnetism, having reported some of the most advanced experimental works in 3D nanomagnetism to date. This includes multiple areas, including 3D nanofabrication, magneto-optics, X-ray microscopy and new effects in multi-layered systems. The main research areas in which we are currently working are explained below. For more details, see our Publications.

3D nanofabrication

3D printing at the nanoscale

Demonstration of FEBID

We pioneer nanoscale 3D printing methods based on focused electrons, ions, and photons for the fabrication of nanomaterials and devices. Advanced algorithms developed in our group enable the creation of highly complex nanostructures with true nanoscale resolution. These approaches allow the realization of magnetic and superconducting 3D nanostructures, topological objects, and corrugated surfaces, making them uniquely suited for advanced nano-prototyping and moderate-throughput nanofabrication.

3D spintronics

New effects in magnetic multilayers

Demonstration of interlayer DMI

We investigate new forms of coupling between magnetic layers in multilayered heterostructures for applications in 3D spintronics. This includes the experimental discovery of interlayer chiral spin interactions and the emergence of curvilinear effects in nano-curved substrates.

3D magnetic circuits

Demonstration of 3D magnetic circuit

We study the efficient motion of domain walls and skyrmions in three dimensions, the emergence of novel magnetotransport and spin-transport effects in 3D geometries, and the imprinting of topological magnetic states via 3D nanopatterning.

Magneto-optics & microscopy in 3D

Dark-field MOKE magnetometry

Demonstration of MOKE

We develop new magneto-optical techniques for the advanced characterization of 3D nanostructures and thin-film multilayers. These techniques allow us to probe single 3D nano-objects, resolve their magnetic vector field configurations, image their domain states over long working distances, and explore new photonic–spintronic paradigms.

X-ray and electron microscopy

Demonstration of magnetization in the artificial double-helix.

In collaboration with colleagues at large X-ray and electron microscopy facilities, we access their  3D magnetic states at nanometric resolution via tomographic reconstructions.