Engineering Spin-Splitting in Atomically Thin 2D Non-Centrosymmetric Crystals

MSCA (Marie Skłodowska-Curie)HORIZON-TMA-MSCA-PF-EFID: 101107842
EC Contribution
€1,812
Consortium Size
2 orgs
Start Year
2024
Summary

The information technology and communication sector (ICT) has been undergoing remarkable progress fuelled by integrational advancements in its building blocks, the field effect transistor (FET). The FETs in commercials microprocessors still use more than half a century old energy-intensive conductance switching processes to perform logic operations. It is well understood that the inability to remove the dissipated energy in such switching process will eventually stop the ongoing downscaling of the microprocessors in the next few years. Spintronic-based devices, working by virtue of energy efficient switching the spin-polarization, are considered to bring a paradigm shift in logic operations. Such devices use charge-to-spin interconversion (CSI) which is maximized in materials with strong spin-orbit coupling (SOC). The main goal of ACCESS is to engineer inversion symmetry and SOC in vertical heterostructures of two-dimensional layered materials (2DLMs) to facilitate the CSI process. We shall fabricate dual gated hBN encapsulated FETs using the 1T' phase of transitional metal dichalcogenides and its twisted bilayers to tune symmetry and SOC. ACCESS will exploit the Edelstein effect and intrinsic Berry curvature dipole to generate current-induced magnetization and detect it via unidirectional magnetoresistance (UMR) and nonlinear Hall effect (NHE) measurements. The CSI in our samples will be further tuned by dynamically varying vertical displacement field and the charge carrier density in the channel. By this way, ACCESS will harness the topological properties of 2DLMs for applications in future spintronics devices, capable of magnet-free spin-to-charge interconversion. Besides its scientific goals, ACCESS also focuses on strengthening the researcher’s transferable skills and providing him a high-quality interdisciplinary research training, helping him to build a promising scientific research career.

Consortium (2)

Project Results (6)

Source: CORDIS, the EU research results database.

Publications (4)
Second-Order Conductivity Probes a Cascade of Singularities in a Moiré Superlattice
ACS Nano· 2025DOI
Tanweer Ahmed, Bao Q. Tu, Kenji Watanabe, Takashi Taniguchi, Marco Gobbi, Fèlix Casanova, Luis E. Hueso
Second‐Order Synaptic Memory using Inherent Plasticity of Moiré Superlattices
Advanced Materials· 2025DOI
Tanweer Ahmed, Kenji Watanabe, Takashi Taniguchi, Fèlix Casanova, Luis E. Hueso
Small
Small· 2025DOI
Tanweer Ahmed, Harsh Varshney, Bao Q. Tu, Kenji Watanabe, Takashi Taniguchi, Marco Gobbi, Fèlix Casanova, Amit Agarwal, Luis E. Hueso
Unveiling Intrinsic Bulk Photovoltaic Effect in Atomically Thin ReS<sub>2</sub>
Nano Letters· 2024DOI
Maria Ramos, Tanweer Ahmed, Bao Q. Tu, Eleni Chatzikyriakou, Lucía Olano-Vegas, Beatriz Martín-García, M. Reyes Calvo, Stepan S. Tsirkin, Ivo Souza, Félix Casanova, Fernando de Juan, Marco Gobbi, Luis E. Hueso
Deliverables (2)