Your search keyword '"Dappe YJ"' showing total 4 results

1. Hybrid molecular graphene transistor as an operando and optoelectronic platform.

Author

Trasobares J, Martín-Romano JC, Khaliq MW, Ruiz-Gómez S, Foerster M, Niño MÁ, Pedraz P, Dappe YJ, de Ory MC, García-Pérez J, Acebrón M, Osorio MR, Magaz MT, Gomez A, Miranda R, and Granados D

Abstract

Lack of reproducibility hampers molecular devices integration into large-scale circuits. Thus, incorporating operando characterization can facilitate the understanding of multiple features producing disparities in different devices. In this work, we report the realization of hybrid molecular graphene field effect transistors (m-GFETs) based on 11-(Ferrocenyl)undecanethiol (FcC 11 SH) micro self-assembled monolayers (μSAMs) and high-quality graphene (Gr) in a back-gated configuration. On the one hand, Gr enables redox electron transfer, avoids molecular degradation and permits operando spectroscopy. On the other hand, molecular electrode decoration shifts the Gr Dirac point (V DP ) to neutrality and generates a photocurrent in the Gr electron conduction regime. Benefitting from this heterogeneous response, the m-GFETs can implement optoelectronic AND/OR logic functions. Our approach represents a step forward in the field of molecular scale electronics with implications in sensing and computing based on sustainable chemicals., (© 2023. The Author(s).)

Published

2023

2. Flat epitaxial quasi-1D phosphorene chains.

Author

Zhang W, Enriquez H, Tong Y, Mayne AJ, Bendounan A, Smogunov A, Dappe YJ, Kara A, Dujardin G, and Oughaddou H

Abstract

The emergence of peculiar phenomena in 1D phosphorene chains (P chains) has been proposed in theoretical studies, notably the Stark and Seebeck effects, room temperature magnetism, and topological phase transitions. Attempts so far to fabricate P chains, using the top-down approach starting from a few layers of bulk black phosphorus, have failed to produce reliably precise control of P chains. We show that molecular beam epitaxy gives a controllable bottom-up approach to grow atomically thin, crystalline 1D flat P chains on a Ag(111) substrate. Scanning tunneling microscopy, angle-resolved photoemission spectroscopy, and density functional theory calculations reveal that the armchair-shaped chains are semiconducting with an intrinsic 1.80 ± 0.20 eV band gap. This could make these P chains an ideal material for opto-electronic devices., (© 2021. The Author(s).)

Published

2021

3. Engineering the magnetic coupling and anisotropy at the molecule-magnetic surface interface in molecular spintronic devices.

Author

Campbell VE, Tonelli M, Cimatti I, Moussy JB, Tortech L, Dappe YJ, Rivière E, Guillot R, Delprat S, Mattana R, Seneor P, Ohresser P, Choueikani F, Otero E, Koprowiak F, Chilkuri VG, Suaud N, Guihéry N, Galtayries A, Miserque F, Arrio MA, Sainctavit P, and Mallah T

Abstract

A challenge in molecular spintronics is to control the magnetic coupling between magnetic molecules and magnetic electrodes to build efficient devices. Here we show that the nature of the magnetic ion of anchored metal complexes highly impacts the exchange coupling of the molecules with magnetic substrates. Surface anchoring alters the magnetic anisotropy of the cobalt(II)-containing complex (Co(Pyipa) 2 ), and results in blocking of its magnetization due to the presence of a magnetic hysteresis loop. In contrast, no hysteresis loop is observed in the isostructural nickel(II)-containing complex (Ni(Pyipa) 2 ). Through XMCD experiments and theoretical calculations we find that Co(Pyipa) 2 is strongly ferromagnetically coupled to the surface, while Ni(Pyipa) 2 is either not coupled or weakly antiferromagnetically coupled to the substrate. These results highlight the importance of the synergistic effect that the electronic structure of a metal ion and the organic ligands has on the exchange interaction and anisotropy occurring at the molecule-electrode interface.

Published

2016

4. Molecular-scale dynamics of light-induced spin cross-over in a two-dimensional layer.

Author

Bairagi K, Iasco O, Bellec A, Kartsev A, Li D, Lagoute J, Chacon C, Girard Y, Rousset S, Miserque F, Dappe YJ, Smogunov A, Barreteau C, Boillot ML, Mallah T, and Repain V

Abstract

Spin cross-over molecules show the unique ability to switch between two spin states when submitted to external stimuli such as temperature, light or voltage. If controlled at the molecular scale, such switches would be of great interest for the development of genuine molecular devices in spintronics, sensing and for nanomechanics. Unfortunately, up to now, little is known on the behaviour of spin cross-over molecules organized in two dimensions and their ability to show cooperative transformation. Here we demonstrate that a combination of scanning tunnelling microscopy measurements and ab initio calculations allows discriminating unambiguously between both states by local vibrational spectroscopy. We also show that a single layer of spin cross-over molecules in contact with a metallic surface displays light-induced collective processes between two ordered mixed spin-state phases with two distinct timescale dynamics. These results open a way to molecular scale control of two-dimensional spin cross-over layers.

Published

2016