Your search keyword '"Bonell, Frederic"' showing total 16 results

1. Magnetic evolution of Cr$_2$Te$_3$ epitaxially grown on graphene with post-growth annealing

Author

Guillet, Quentin, Boukari, Hervé, Choueikani, Fadi, Ohresser, Philippe, Ouerghi, Abdelkarim, Mesple, Florie, Renard, Vincent T., Jacquot, Jean-François, Jalabert, Denis, Vergnaud, Céline, Bonell, Frédéric, Marty, Alain, and Jamet, Matthieu

Subjects

Condensed Matter - Materials Science

Abstract

Two-dimensional and van der Waals ferromagnets are ideal platform to study low dimensional magnetism and proximity effects in van der Waals heterostructures. Their ultimate two dimensional character offers also the opportunity to easily adjust their magnetic properties using strain or electric fields. Among 2D ferromagnets, the Cr$_{1+x}$Te$_2$ compounds with $x$=0-1 are very promising because their magnetic properties depend on the amount of self-intercalated Cr atoms between pure CrTe$_2$ layers and the Curie temperature (T$_C$) can reach room temperature for certain compositions. Here, we investigate the evolution of the composition, structural and magnetic properties of thin Cr$_{1.33}$Te$_2$ (Cr$_2$Te$_3$) films epitaxially grown on graphene upon annealing. We observe a transition above 450{\deg}C from the Cr$_{1.33}$Te$_2$ phase with perpendicular magnetic anisotropy and a T$_C$ of 180 K to a composition close to Cr$_{1.39}$Te$_2$ with in-plane magnetic anisotropy and a T$_C$ of 240-250 K. This phase remains stable up to 650{\deg}C above which a pure Cr film starts to form. This work demonstrates the complex interplay between intercalated Cr, lattice parameters and magnetic properties in Cr$_{1+x}$Te$_2$ compounds., Comment: 5 pages, 5 figures

Published

2024

2. Epitaxial van der Waals heterostructures of Cr2Te3 on 2D materials

Author

Guillet, Quentin, Vojacek, Libor, Dosenovic, Djordje, Ibrahim, Fatima, Boukari, Herve, Li, Jing, Choueikani, Fadi, Ohresser, Philippe, Ouerghi, Abdelkarim, Mesple, Florie, Renard, Vincent, Jacquot, Jean-Francois, Jalabert, Denis, Okuno, Hanako, Chshiev, Mairbek, Vergnaud, Celine, Bonell, Frederic, Marty, Alain, and Jamet, Matthieu

Subjects

Condensed Matter - Materials Science

Abstract

Achieving large-scale growth of two-dimensional (2D) ferromagnetic materials with high Curie temperature (TC) and perpendicular magnetic anisotropy (PMA) is highly desirable for the development of ultra-compact magnetic sensors and magnetic memories. In this context, van der Waals (vdW) Cr2Te3 appears as a promising candidate. Bulk Cr2Te3 exhibits strong PMA and a TC of 180 K. Moreover, both PMA and TC might be adjusted in ultrathin films by engineering composition, strain, or applying an electric field. In this work, we demonstrate the molecular beam epitaxy (MBE) growth of vdW heterostructures of five-monolayer quasi-freestanding Cr2Te3 on three classes of 2D materials: graphene (semimetal), WSe2 (semiconductor) and Bi2Te3 (topological insulator). By combining structural and chemical analysis down to the atomic level with ab initio calculations, we confirm the single crystalline character of Cr2Te3 films on the 2D materials with sharp vdW interfaces. They all exhibit PMA and TC close to the bulk Cr2Te3 value of 180 K. Ab initio calculations confirm this PMA and show how its strength depends on strain. Finally, Hall measurements reveal a strong anomalous Hall effect, which changes sign at a given temperature. We theoretically explain this effect by a sign change of the Berry phase close to the Fermi level. This transition temperature depends on the 2D material in proximity, notably as a consequence of charge transfer. MBE-grown Cr2Te3/2D material bilayers constitute model systems for the further development of spintronic devices combining PMA, large spin-orbit coupling and sharp vdW interface., Comment: 18 pages, 13 figures and Supplemental Material

Published

2023

3. Spin-orbit torque switching in 2D ferromagnet / topological insulator heterostructure grown by molecular beam epitaxy

Author

Guillet, Thomas, Galcera, Regina V., Sierra, Juan F., Costache, Marius V., Jamet, Matthieu, Bonell, Frédéric, and Valenzuela, Sergio O.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Topological insulators (TIs) are a promising class of materials for manipulating the magnetization of an adjacent ferromagnet (FM) through the spin-orbit torque (SOT) mechanism. However, current studies combining TIs with conventional FMs present large device-to-device variations, resulting in a broad distribution of SOT magnitudes. It has been identified that the interfacial quality between the TI and the FM is of utmost importance in determining the nature and efficiency of the SOT. To optimize the SOT magnitude and enable ultra-low-power magnetization switching, an atomically smooth interface is necessary. To this end, we have developed the growth of a full van der Waals FM/TI heterostructure by molecular beam epitaxy. The compensated TI (Bi0.4Sb0.6)2Te3 and ferromagnetic Fe3GeTe2 (FGT) were chosen because of their exceptional crystalline quality, low carrier concentration in BST and relatively large Curie temperature and perpendicular magnetic anisotropy in FGT. We characterized the magnitude of the SOTs by using thorough harmonic magnetotransport measurements and showed that the magnetization of an ultrathin FGT film could be switched with a current density Jc < 10^10 A/m^2. In comparison to previous studies utilizing traditional FMs, our findings are highly reliable, displaying little to no variation between devices.

Published

2023

4. Visualizing giant ferroelectric gating effects in large-scale WSe$_2$/BiFeO$_3$ heterostructures

Author

Salazar, Raphaël, Varotto, Sara, Vergnaud, Céline, Garcia, Vincent, Fusil, Stéphane, Chaste, Julien, Maroutian, Thomas, Marty, Alain, Bonell, Frédéric, Pierucci, Debora, Ouerghi, Abdelkarim, Bertran, François, Fèvre, Patrick Le, Jamet, Matthieu, Bibes, Manuel, and Rault, Julien

Subjects

Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons

Abstract

Multilayers based on quantum materials (complex oxides, topological insulators, transition-metal dichalcogenides, etc) have enabled the design of devices that could revolutionize microelectronics and optoelectronics. However, heterostructures incorporating quantum materials from different families remain scarce, while they would immensely broaden the range of possible applications. Here we demonstrate the large-scale integration of compounds from two highly-multifunctional families: perovskite oxides and transition-metal dichalcogenides (TMDs). We couple BiFeO$_3$, a room-temperature multiferroic oxide, and WSe$_2$, a semiconducting two-dimensional material with potential for photovoltaics and photonics. WSe$_2$ is grown by molecular beam epitaxy and transferred on a centimeter-scale onto BiFeO$_3$ films. Using angle-resolved photoemission spectroscopy, we visualize the electronic structure of 1 to 3 monolayers of WSe$_2$ and evidence a giant energy shift as large as 0.75 eV induced by the ferroelectric polarization direction in the underlying BiFeO$_3$. Such a strong shift opens new perspectives in the efficient manipulation of TMDs properties by proximity effects.

Published

2022

5. Phonon dynamics and thermal conductivity of PtSe2 thin films: Impact of crystallinity and film thickness on heat dissipation

Author

Sachat, Alexandros El, Xiao, Peng, Donadio, Davide, Bonell, Frédéric, Sledzinska, Marianna, Marty, Alain, Vergnaud, Céline, Boukari, Hervé, Jamet, Matthieu, Arregui, Guillermo, Chen, Zekun, Alzina, Francesc, Torres, Clivia M. Sotomayor, and Chavez-Angel, Emigdio

Subjects

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

Abstract

We present a comparative investigation of the influence of crystallinity and film thickness on the acoustic and thermal properties of 2D layered PtSe2 thin films of varying thickness (0.6-24 nm) by combining a set of experimental techniques, namely, frequency domain thermo-reflectance, low-frequency Raman and pump-probe coherent phonon spectroscopy. We find a 35% reduction in the cross-plane thermal conductivity of polycrystalline films with thickness larger than 12 nm compared to the crystalline films of the same thickness due to phonon grain boundary scattering. Density functional theory calculations are in good agreement with the experiments and further reveal the ballistic nature of cross-plane heat transport in PtSe2 up to a certain thickness (~20 nm). In addition, our experiments revealed strong interlayer interactions in PtSe2, short acoustic phonon lifetimes in the range of picoseconds, out-of-plane elastic constant C33=31.8 GPa and layer-dependent group velocity ranging from 1340 m/s in bilayer PtSe2 to 1873 m/s in 8 layers of PtSe2. The potential of tuning the lattice cross-plane thermal conductivity of layered 2D materials with the level of crystallinity and the real-time observation of coherent phonon dynamics, which have direct implications on the cooling and transport of electrons, open a new playground for research in 2D thermoelectric devices and provide guidelines for thermal management in 2D electronics., Comment: 32 pages

Published

2021

6. High carrier mobility in single-crystal PtSe2 grown by molecular beam epitaxy on ZnO(0001)

Author

Bonell, Frédéric, Marty, Alain, Vergnaud, Céline, Consonni, Vincent, Okuno, Hanako, Ouerghi, Abdelkarim, Boukari, Hervé, and Jamet, Matthieu

Subjects

Condensed Matter - Materials Science

Abstract

PtSe2 is attracting considerable attention as a high mobility two-dimensional material with envisionned applications in microelectronics, photodetection and spintronics. The growth of high quality PtSe2 on insulating substrates with wafer-scale uniformity is a prerequisite for electronic transport investigations and practical use in devices. Here, we report the growth of highly oriented few-layers PtSe2 on ZnO(0001) by molecular beam epitaxy. The crystalline structure of the films is characterized with electron and X-ray diffraction, atomic force microscopy and transmission electron microscopy. The comparison with PtSe2 layers grown on graphene, sapphire, mica, SiO2 and Pt(111) shows that among insulating substrates, ZnO(0001) yields films of superior structural quality. Hall measurements performed on epitaxial ZnO/PtSe2 with 5 monolayers of PtSe2 show a clear semiconducting behaviour and a high mobility in excess of 200 cm2V 1s-1 at room temperature and up to 447 cm2V-1s-1 at low temperature.

Published

2021

7. Large-scale epitaxy of two-dimensional van der Waals room-temperature ferromagnet Fe5GeTe2

Author

Ribeiro, Mário, Gentile, Giulio, Marty, Alain, Dosenovic, Djordje, Okuno, Hanako, Vergnaud, Céline, Jacquot, Jean-François, Jalabert, Denis, Longo, Danilo, Ohresser, Philippe, Hallal, Ali, Chshiev, Mairbek, Boulle, Olivier, Bonell, Frédéric, and Jamet, Matthieu

Subjects

Condensed Matter - Materials Science

Abstract

In recent years, two-dimensional van der Waals materials have emerged as an important platform for the observation of long-range ferromagnetic order in atomically thin layers. Although heterostructures of such materials can be conceived to harness and couple a wide range of magneto-optical and magneto-electrical properties, technologically relevant applications require Curie temperatures at or above room-temperature and the ability to grow films over large areas. Here we demonstrate the large-area growth of single-crystal ultrathin films of stoichiometric Fe5GeTe2 on an insulating substrate using molecular beam epitaxy. Magnetic measurements show the persistence of soft ferromagnetism up to room temperature, with a Curie temperature of 293 K, and a weak out-of-plane magnetocrystalline anisotropy. Surface, chemical, and structural characterizations confirm the layer-by-layer growth, 5:1:2 Fe:Ge:Te stoichiometric elementary composition, and single crystalline character of the films.

Published

2021

8. Control of spin-orbit torques by interface engineering in topological insulator heterostructures

Author

Bonell, Frédéric, Goto, Minori, Sauthier, Guillaume, Sierra, Juan F., Figueroa, Adriana I., Costache, Marius V., Miwa, Shinji, Suzuki, Yoshishige, and Valenzuela, Sergio O.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

(Bi$_{1-x}$Sb$_x$)$_2$Te$_3$ topological insulators (TIs) are gathering increasing attention owing to their large charge-to-spin conversion efficiency and the ensuing spin-orbit torques (SOTs) that can be used to manipulate the magnetization of a ferromagnet (FM). The origin of the torques, however, remains elusive, while the implications of hybridized states and the strong material intermixing at the TI/FM interface are essentially unexplored. By combining interface chemical analysis and spin-transfer ferromagnetic resonance (ST-FMR) measurements, we demonstrate that intermixing plays a critical role in the generation of SOTs. By inserting a suitable normal metal spacer, material intermixing is reduced and the TI properties at the interface are largely improved, resulting in strong variations in the nature of the SOTs. A dramatic enhancement of a field-like torque, opposing and surpassing the Oersted-field torque, is observed, which can be attributed to the non-equilibrium spin density in Rashba-split surface bands and to the suppression of spin memory loss., Comment: This document is the unedited Author's version of a Submitted Work that was subsequently accepted for publication in Nanoletters, \copyright American Chemical Society after peer review

Published

2020

9. A Molecular Approach for Engineering Interfacial Interactions in Magnetic-Topological Insulator Heterostructures

Author

Cuxart, Marc G., Valbuena, Miguel Angel, Robles, Roberto, Moreno, César, Bonell, Frédéric, Sauthier, Guillaume, Imaz, Inhar, Xu, Heng, Nistor, Corneliu, Barla, Alessandro, Gargiani, Pierluigi, Valvidares, Manuel, Maspoch, Daniel, Gambardella, Pietro, Valenzuela, Sergio O., and Mugarza, Aitor

Subjects

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

Abstract

Controlling interfacial interactions in magnetic/topological insulator heterostructures is a major challenge for the emergence of novel spin-dependent electronic phenomena. As for any rational design of heterostructures that rely on proximity effects, one should ideally retain the overall properties of each component while tuning interactions at the interface. However, in most inorganic interfaces interactions are too strong, consequently perturbing, and even quenching, both the magnetic moment and the topological surface states at each side of the interface. Here we show that these properties can be preserved by using ligand chemistry to tune the interaction of magnetic ions with the surface states. By depositing Co-based porphyrin and phthalocyanine monolayers on the surface of Bi$_2$Te$_3$ thin films, robust interfaces are formed that preserve undoped topological surface states as well as the pristine magnetic moment of the divalent Co ions. The selected ligands allow us to tune the interfacial hybridization within this weak interaction regime. These results, which are in stark contrast with the observed suppression of the surface state at the first quintuple layer of Bi$_2$Se$_3$ induced by the interaction with Co phthalocyanines, demonstrate the capability of planar metal-organic molecules to span interactions from the strong to the weak limit.

Published

2020

10. Determination of the spin-lifetime anisotropy in graphene using oblique spin precession

Author

Raes, Bart, Scheerder, Jeroen E., Costache, Marius V., Bonell, Frédéric, Sierra, Juan F., Cuppens, Jo, Van de Vondel, Joris, and Valenzuela, Sergio O.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We determine the spin-lifetime anisotropy of spin-polarized carriers in graphene. In contrast to prior approaches, our method does not require large out-of-plane magnetic fields and thus it is reliable for both low- and high-carrier densities. We first determine the in-plane spin lifetime by conventional spin precession measurements with magnetic fields perpendicular to the graphene plane. Then, to evaluate the out-of-plane spin lifetime, we implement spin precession measurements under oblique magnetic fields that generate an out-of-plane spin population. We find that the spin-lifetime anisotropy of graphene on silicon oxide is independent of carrier density and temperature down to 150 K, and much weaker than previously reported. Indeed, within the experimental uncertainty, the spin relaxation is isotropic. Altogether with the gate dependence of the spin lifetime, this indicates that the spin relaxation is driven by magnetic impurities or random spin-orbit or gauge fields., Comment: Final version published in Nature Communications under a Creative Commons Attribution 4.0 International License

Published

2018

11. Strongly anisotropic spin relaxation in graphene/transition metal dichalcogenide heterostructures at room temperature

Author

Benítez, Luis. A., Sierra, Juan. F., Torres, Williams Savero, Arrighi, Aloïs, Bonell, Frédéric, Costache, Marius. V., and Valenzuela, Sergio. O.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Graphene has emerged as the foremost material for future two-dimensional spintronics due to its tuneable electronic properties. In graphene, spin information can be transported over long distances and, in principle, be manipulated by using magnetic correlations or large spin-orbit coupling (SOC) induced by proximity effects. In particular, a dramatic SOC enhancement has been predicted when interfacing graphene with a semiconducting transition metal dechalcogenide, such as tungsten disulphide (WS$_2$). Signatures of such an enhancement have recently been reported but the nature of the spin relaxation in these systems remains unknown. Here, we unambiguously demonstrate anisotropic spin dynamics in bilayer heterostructures comprising graphene and WS$_2$. By using out-of-plane spin precession, we show that the spin lifetime is largest when the spins point out of the graphene plane. Moreover, we observe that the spin lifetime varies over one order of magnitude depending on the spin orientation, indicating that the strong spin-valley coupling in WS$_2$ is imprinted in the bilayer and felt by the propagating spins. These findings provide a rich platform to explore coupled spin-valley phenomena and offer novel spin manipulation strategies based on spin relaxation anisotropy in two-dimensional materials.

Published

2017

12. Bias dependence of tunneling magnetoresistance in magnetic tunnel junctions with asymmetric barriers

Author

Kalitsov, Alan, Zermatten, Pierre-Jean, Bonell, Frédéric, Gaudin, Gilles, Andrieu, Stéphane, Tiusan, Coriolan, Chshiev, Mairbek, and Velev, Julian P.

Subjects

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

Abstract

The transport properties of magnetic tunnel junctions (MTJs) are very sensitive to interface modifications. In this work we investigate both experimentally and theoretically the effect of asymmetric barrier modifications on the bias dependence of tunneling magnetoresistance (TMR) in single crystal Fe/MgO-based MTJs with (i) one crystalline and one rough interface and (ii) with a monolayer of O deposited at the crystalline interface. In both cases we observe an asymmetric bias dependence of TMR and a reversal of its sign at large bias. We propose a general model to explain the bias dependence in these and similar systems reported earlier. The model predicts the existence of two distinct TMR regimes: (i) tunneling regime when the interface is modified with layers of a different insulator and (ii) resonant regime when thin metallic layers are inserted at the interface. We demonstrate that in the tunneling regime negative TMR is due to the high voltage which overcomes the exchange splitting in the electrodes, while the asymmetric bias dependence of TMR is due to the interface transmission probabilities. In the resonant regime inversion of TMR could happen at zero voltage depending on the alignment of the resonance levels with the Fermi surfaces of the electrodes. Moreover, the model predicts a regime in which TMR has different sign at positive and negative bias suggesting possibilities of combining memory with logic functions.

Published

2013

13. Electron diffraction study of the plastic relaxation of MgO epitaxially grown on BCC FeV(001) alloys by varying the lattice mismatch

Author

Bonell, Frédéric and Andrieu, Stéphane

Published

2017

14. MgO-based epitaxial magnetic tunnel junctions using Fe-V electrodes

Author

Bonell, Frederic, Andrieu, Stephane, Bertran, Francois, Lefevre, Patrick, Ibrahimi, Amina Taleb, Snoeck, Etienne, Tiusan, Coriolan-Viorel, and Montaigne, Francois

Subjects

Epitaxy -- Observations, Magnetoresistance -- Observations, Business, Electronics, Electronics and electrical industries

Published

2009

15. The search for manganese incorporation in MoSe$_{{2}}$ monolayer epitaxially grown on graphene

Author

Gay, Maxime, Dau, Minh-Tuan, Vergnaud, Céline, Marty, Alain, Bonell, Frédéric, Boukari, Hervé, Paillet, Colin, Hyot, Bérangère, Okuno, Hanako, Mallet, Pierre, Veuillen, Jean-Yves, Renault, Olivier, and Jamet, Matthieu

Subjects

2D materials, Magnetic doping, Molecular beam epitaxy, Transmission electron microscopy, Scanning tunneling microscopy, Momentum resolved photoemission electron microscopy, Physics, QC1-999

Abstract

The introduction of magnetism in two-dimensional (2D) materials represents an intense field of research nowadays and the quest to reach above-room-temperature ordering temperatures is still underway. Intrinsic ferromagnetism was discovered in 2017 in CrI$_{{3}}$ and Cr$_{{2}}$Ge$_{{2}}$Te$_{{6}}$ in the monolayer form with low Curie temperatures. An alternative method to introduce magnetism into conventional 2D materials is substitutional doping with magnetic impurities similarly to three-dimensional diluted magnetic semiconductors. The case of Mn-doped transition metal dichalcogenide (MoS$_{{2}}$, MoSe$_{{2}}$, WS$_{{2}}$, WSe$_{{2}}$) monolayers is very interesting because combining out-of-plane ferromagnetism and valley contrast leads to ferrovalley materials. In this work, we focus on the incorporation of Mn in MoSe$_{{2}}$ by molecular beam epitaxy on graphene which has been rarely addressed up to now. By using a multiscale characterization approach, we demonstrate that Mn atoms are incorporated into the MoSe$_{{2}}$ monolayer up to 5 atomic percent. However, when incorporated into the film, Mn atoms tend to diffuse to the grain edges forming undefined Mo$_{{{\it x}}}$Mn$_{{{\it y}}}$Se$_{{{\it z}}}$ phase at grain boundaries after completion of the MoSe$_{{2}}$ monolayer. This segregation leaves the crystalline and electronic structure of MoSe$_{{2}}$ unmodified. Above 5%, the saturation of Mn content in MoSe$_{{2}}$ leads to the formation of epitaxial MnSe clusters.

Published

2021

16. Control of Spin-Orbit Torques by Interface Engineering in Topological Insulator Heterostructures

Author

'Bonell, Frederic