Magnetic moments near zigzag edges in graphene allow complex nanostructures with customised spin properties to be realised. However, computational costs restrict theoretical investigations to small or perfectly periodic structures. Here we demonstrate that a machine-learning approach, using only geometric input, can accurately estimate magnetic moment profiles, allowing arbitrarily large and disordered systems to be quickly simulated. Excellent agreement is found with mean-field Hubbard calculations, and important electronic, magnetic and transport properties are reproduced using the estimated profiles. This approach allows the magnetic moments of experimental-scale systems to be quickly and accurately predicted, and will speed-up the ident...
We present a scalable machine learning (ML) model to predict local electronic properties such as on-...
We estimate the spatial distribution of heterogeneous physical parameters involved in the formation ...
Funding Information: The ion-beam experiments were performed at the LEIBF beamline of Inter Universi...
Magnetic materials are crucial components of many technologies that could drive the ecological trans...
Antiferromagnetic materials are exciting quantum materials with rich physics and great potential for...
Two-dimensional (2D) magnets have transformative potential in spintronics applications. In this stud...
Supervised machine learning algorithms, such as graph neural networks (GNN), have successfully predi...
The Fe14Nd2B-based permanent magnets are technologically sought-after for energy conversion due to t...
In the development of materials, the understanding of their properties is crucial. For magnetic mate...
Understanding spin textures in magnetic systems is extremely important to the spintronics and it is ...
We introduce a multi-tasking graph convolutional neural network, HydraGNN, to simultaneously predict...
The objective of this paper is to investigate the ability of physics-informed neural networks to lea...
Edge magnetism in zigzag transition metal dichalcogenide nanoribbons is studied using a three-band t...
The magnetic interaction between a pair of atoms can be determined by calculating the value of the q...
proposed a strategy for constructing graphene fragments (nanoflakes) with large electron spin magnet...
We present a scalable machine learning (ML) model to predict local electronic properties such as on-...
We estimate the spatial distribution of heterogeneous physical parameters involved in the formation ...
Funding Information: The ion-beam experiments were performed at the LEIBF beamline of Inter Universi...
Magnetic materials are crucial components of many technologies that could drive the ecological trans...
Antiferromagnetic materials are exciting quantum materials with rich physics and great potential for...
Two-dimensional (2D) magnets have transformative potential in spintronics applications. In this stud...
Supervised machine learning algorithms, such as graph neural networks (GNN), have successfully predi...
The Fe14Nd2B-based permanent magnets are technologically sought-after for energy conversion due to t...
In the development of materials, the understanding of their properties is crucial. For magnetic mate...
Understanding spin textures in magnetic systems is extremely important to the spintronics and it is ...
We introduce a multi-tasking graph convolutional neural network, HydraGNN, to simultaneously predict...
The objective of this paper is to investigate the ability of physics-informed neural networks to lea...
Edge magnetism in zigzag transition metal dichalcogenide nanoribbons is studied using a three-band t...
The magnetic interaction between a pair of atoms can be determined by calculating the value of the q...
proposed a strategy for constructing graphene fragments (nanoflakes) with large electron spin magnet...
We present a scalable machine learning (ML) model to predict local electronic properties such as on-...
We estimate the spatial distribution of heterogeneous physical parameters involved in the formation ...
Funding Information: The ion-beam experiments were performed at the LEIBF beamline of Inter Universi...