Your search keyword '"Castenetto, Pauline"' showing total 4 results

1. Stability of edge magnetism against disorder in zigzag MoS$_2$ nanoribbons

Author

Vancsó, Péter, Hagymási, Imre, Castenetto, Pauline, and Lambin, Philippe

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Molybdenum disulfide nanoribbons with zigzag edges show ferromagnetic and metallic properties based on previous \emph{ab-initio} calculations. The investigation of the role of disorder on the magnetic properties is, however, still lacking due to the computational costs of these methods. In this work we fill this gap by studying the magnetic and electronic properties of several nanometer long MoS$_2$ zigzag nanoribbons using tight-binding and Hubbard Hamiltonians. Our results reveal that proper tight-binding parameters for the edge atoms are crucial to obtain quantitatively the metallic states and the magnetic properties of MoS$_2$ nanoribbons. With the help of the fine-tuned parameters, we perform large-scale calculations and predict the spin domain-wall energy along the edges, which is found to be significantly lower compared to that of the zigzag graphene nanoribbons. The tight-binding approach allows us to address the effect of edge disorder on the magnetic properties. Our results open the way for investigating electron-electron effects in realistic-size nanoribbon devices in MoS$_2$ and also provide valuable information for spintronic applications., Comment: 8 pages, 7 figures

Published

2019

2. Edge Magnetism in MoS2 Nanoribbons: Insights from a Simple One-Dimensional Model

Author

Castenetto, Pauline, primary, Lambin, Philippe, additional, and Vancsó, Péter, additional

Published

2023

3. Edge Magnetism in MoS 2 Nanoribbons: Insights from a Simple One-Dimensional Model.

Author

Castenetto, Pauline, Lambin, Philippe, and Vancsó, Péter

Subjects

*NANORIBBONS, *MAGNETISM, *DENSITY functional theory, *SPIN polarization, *FERMI level

Abstract

Edge magnetism in zigzag nanoribbons of monolayer MoS 2 has been investigated with both density functional theory and a tight-binding plus Hubbard (TB+U) Hamiltonian. Both methods revealed that one band crossing the Fermi level is more strongly influenced by spin polarization than any other bands. This band originates from states localized on the sulfur edge of the nanoribbon. Its dispersion closely resembles that of the energy branch obtained in a linear chain of atoms with first-neighbor interaction. By exploiting this resemblance, a toy model has been designed to study the energetics of different spin configurations of the nanoribbon edge. [ABSTRACT FROM AUTHOR]

Published

2023

4. Stability of edge magnetism against disorder in zigzag MoS2 nanoribbons

Author

Vancsó, Péter, primary, Hagymási, Imre, additional, Castenetto, Pauline, additional, and Lambin, Philippe, additional

Published

2019