Your search keyword '"Toraille, Loïc"' showing total 15 results

1. Imaging the Meissner Effect and Flux Trapping of Superconductors under High Pressure using N-V Centers

Author

Dailledouze, Cassandra, Hilberer, Antoine, Schmidt, Martin, Adam, Marie-Pierre, Toraille, Loïc, Ho, Kin On, Forget, Anne, Colson, Dorothée, Loubeyre, Paul, and Roch, Jean-François

Subjects

Condensed Matter - Superconductivity, Quantum Physics

Abstract

Pressure is a key parameter for tuning or revealing superconductivity in materials and compounds. Many measurements of superconducting phase transition temperatures have been conducted using diamond anvil cells (DACs), which provide a wide pressure range and enable concomitant microscopic structural characterization of the sample. However, the inherently small sample volumes in DACs complicate the unambiguous detection of the Meissner effect, the hallmark of superconductivity. Recently, the Meissner effect in superconductors within a DAC was successfully demonstrated using diamond nitrogen-vacancy (N-V) widefield magnetometry, a non-invasive optical technique. In this work, we show that N-V magnetometry can also map superconductivity with micrometer resolution. We apply this technique to a microcrystal of HgBa$_2$Ca$_2$Cu$_3$O$_{8+\delta}$ (Hg-1223) mercury-based cuprate superconductor under 4 GPa of pressure. The method is capable to detect the magnetic field expulsion and heterogeneities in the sample, visible in a set of characteristic parameters as the local critical temperature $T_{c}$. Flux pinning zones are identified through flux trapping maps. This approach could enable detailed investigations of superconductivity of a broad range of materials under high-pressure conditions.

Published

2025

2. NV center magnetometry up to 130 GPa as if at ambient pressure

Author

Hilberer, Antoine, Toraille, Loïc, Dailledouze, Cassandra, Adam, Marie-Pierre, Hanlon, Liam, Weck, Gunnar, Schmidt, Martin, Loubeyre, Paul, and Roch, Jean-François

Subjects

Quantum Physics, Physics - Applied Physics

Abstract

Engineering a layer of nitrogen-vacancy (NV) centers on the tip of a diamond anvil creates a multipurpose quantum sensors array for high pressure measurements, especially for probing magnetic and superconducting properties of materials. Expanding this concept above 100 GPa appears to be a substantial challenge. We observe that deviatoric stress on the anvil tip sets a limit at 40-50 GPa for practical magnetic measurements based on optically detected magnetic resonance (ODMR) of NV centers under pressure. We show that this limit can be circumvented up to at least 130 GPa by machining a micropillar on the anvil tip to create a quasi-hydrostatic stress environment for the NV centers. This is quantified using the pressure dependence of the diamond Raman shift, the NV ODMR dependence on applied magnetic field, and NV photoluminescence spectral shift. This paves the way for direct and reliable detection of the Meissner effect in superconductors above 100 GPa, such as super-hydrides., Comment: 5 pages, 4 figures

Published

2023

3. Optical properties of SiV and GeV color centers in nanodiamonds under hydrostatic pressures up to 180 GPa

Author

Vindolet, Baptiste, Adam, Marie-Pierre, Toraille, Loïc, Chipaux, Mayeul, Hilberer, Antoine, Dupuy, Géraud, Razinkovas, Lukas, Alkauskas, Audrius, Thiering, Gergő, Gali, Adam, De Feudis, Mary, Ngambou, Midrel Wilfried Ngandeu, Achard, Jocelyn, Tallaire, Alexandre, Schmidt, Martin, Becher, Christoph, and Roch, Jean-François

Subjects

Quantum Physics, Condensed Matter - Materials Science

Abstract

We investigate the optical properties of silicon-vacancy (SiV) and germanium-vacancy (GeV) color centers in nanodiamonds under hydrostatic pressure up to 180 GPa. The nanodiamonds were synthetized by Si or Ge-doped plasma assisted chemical vapor deposition and, for our experiment, pressurized in a diamond anvil cell. Under hydrostatic pressure we observe blue-shifts of the SiV and GeV zero-phonon lines by 17 THz (70 meV) and 78 THz (320 meV), respectively. These measured pressure induced shifts are in good agreement with ab initio calculations that take into account the lattice compression based on the equation of state of diamond and that are extended to the case of the tin-vacancy (SnV) center. This work provides guidance on the use of group-IV-vacancy centers as quantum sensors under extreme pressures that will exploit their specific optical and spin properties induced by their intrinsic inversion-symmetric structure., Comment: 7 pages, 4 figures

Published

2022

4. Synthesis of Laves phase hydrides YFe2H6 and YFe2H7 at high pressure: Reaching a limit of interstitial hydrogen uptake

Author

Caussé, Maélie, Geneste, Grégory, Toraille, Loïc, Guigue, Bastien, Charraud, Jean-Baptiste, Paul-Boncour, Valérie, and Loubeyre, Paul

Published

2025

5. Ethane under pressure revisited using x-ray diffraction, Raman spectroscopy, infrared absorption, and ab initio calculations up to 150 GPa.

Author

Toraille, Loïc, Weck, Gunnar, Geneste, Grégory, Pépin, Charles, Garbarino, Gaston, and Loubeyre, Paul

Subjects

*AB-initio calculations, *RAMAN spectroscopy, *X-ray diffraction, *INFRARED absorption, *PHASE transitions, *INFRARED spectroscopy

Abstract

Ethane ( C 2 H 6 ) is anticipated to be the most stable compound within the carbon–hydrogen system under the 100 GPa pressure range. Nevertheless, the properties of ethane under pressure are still poorly documented. Here, we present a comprehensive study of the structural and vibrational properties of C 2 H 6 in a diamond anvil cell at pressures up to 150 GPa. To obtain detailed data, ethane single-crystal was grown in a helium pressure-transmitting medium. Utilizing single-crystal x-ray diffraction, the distortion mechanism between the tetragonal and monoclinic phases, occurring over the 3.2–5.2 GPa pressure range, is disclosed. Subsequently, no phase transition is observed up to 150 GPa. The accurately measured compression curve is compared to various computational approximations. The vibrational modes measured by Raman spectroscopy and infrared absorption are well identified, and their evolution is well reproduced by ab initio calculations. In particular, an unusual anticrossing phenomenon occurs near 40 GPa between a rocking and a stretching mode, likely attributable to intermolecular interactions through hydrogen bonding. [ABSTRACT FROM AUTHOR]

Published

2024

6. Combined synchrotron X-ray diffraction and NV diamond magnetic microscopy measurements at high pressure

Author

Toraille, Loïc, Hilberer, Antoine, Plisson, Thomas, Lesik, Margarita, Chipaux, Mayeul, Vindolet, Baptiste, Pépin, Charles, Occelli, Florent, Schmidt, Martin, Debuisschert, Thierry, Guignot, Nicolas, Itié, Jean-Paul, Loubeyre, Paul, and Roch, Jean-François

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Quantum Physics

Abstract

We report the possibility to simultaneously perform wide-field nitrogen-vacancy (NV) diamond magnetic microscopy and synchrotron X-ray diffraction (XRD) measurements at high pressure. NV color centers are created on the culet of a diamond anvil which is integrated in a diamond anvil cell for static compression of the sample. The optically detected spin resonance of the NV centers is used to map the stray magnetic field produced by the sample magnetization. Using this combined scheme, the magnetic and structural behaviors can be simultaneously measured. As a proof-of-principle, we record the correlated {\alpha}-Fe to {\epsilon}-Fe structural and magnetic transitions of iron that occur here between 15 and 20 GPa at 300 K., Comment: 12 pages, 4 figures

Published

2020

7. Magnetic measurements on micron-size samples under high pressure using designed NV centers

Author

Lesik, Margarita, Plisson, Thomas, Toraille, Loïc, Renaud, Justine, Occelli, Florent, Schmidt, Martin, Salord, Olivier, Delobbe, Anne, Debuisschert, Thierry, Rondin, Loïc, Loubeyre, Paul, and Roch, Jean-François

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Pressure is a unique tool to tune the interplay between structural, electronic and magnetic interactions. It leads to remarkable properties of materials such as recent temperature records in superconductivity. Advanced magnetic measurements under very high pressure in the Diamond Anvil Cell (DAC) use synchrotron approaches but these are lacking a formal link to the macroscopic magnetic properties. We report an alternative method consisting in optical magnetometry based on nitrogen-vacancy (NV) centers created at the surface of a diamond anvil. We illustrate the method by two measurements realized at room and low temperature respectively: the pressure evolution of the magnetization of an iron bead up to 30 GPa showing the iron ferromagnetic collapse and the detection of the superconducting transition of MgB2 at 7 GPa., Comment: 15 pages, 4 figures

Published

2018

8. Nitrogen-Vacancy Centers in Diamond for Current Imaging at the Redistributive Layer Level of Integrated Circuits

Author

Nowodzinski, Antoine, Chipaux, Mayeul, Toraille, Loïc, Jacques, Vincent, Roch, Jean-François, and Debuisschert, Thierry

Subjects

Physics - Instrumentation and Detectors, Condensed Matter - Materials Science

Abstract

We present a novel technique based on an ensemble of Nitrogen-Vacancy (NV) centers in diamond to perform Magnetic Current Imaging (MCI) on an Integrated Circuit (IC). NV centers in diamond allow measuring the three components of the magnetic fields generated by a mA range current in an IC structure over a field of 50 x 200 {\mu}m^2 with sub-micron resolution. Vector measurements allow using a more robust algorithm than those used for MCI using Giant Magneto Resistance (GMR) or Superconducting Quantum Interference Device (SQUID) sensors and it is opening new current reconstruction prospects. Calculated MCI from these measurements shows a very good agreement with theoretical current path. Acquisition time is around 10 sec, which is much faster than scanning measurements using SQUID or GMR. The experimental set-up relies on a standard optical microscope, and the measurements can be performed at room temperature and atmospheric pressure. These early experiments, not optimized for IC, show that NV centers in diamond could become a real alternative for MCI in IC., Comment: 7 pages, 4 figures

Published

2015

9. Magnetic measurements on micrometer-sized samples under high pressure using designed NV centers

Author

Lesik, Margarita, Plisson, Thomas, Toraille, Loïc, Renaud, Justine, Occelli, Florent, Schmidt, Martin, Salord, Olivier, Delobbe, Anne, Debuisschert, Thierry, Rondin, Loïc, Loubeyre, Paul, and Roch, Jean-François

Published

2019

10. Optical properties of SiV and GeV color centers in nanodiamonds under hydrostatic pressures up to 180 GPa

Author

Vindolet, Baptiste, primary, Adam, Marie-Pierre, additional, Toraille, Loïc, additional, Chipaux, Mayeul, additional, Hilberer, Antoine, additional, Dupuy, Géraud, additional, Razinkovas, Lukas, additional, Alkauskas, Audrius, additional, Thiering, Gergő, additional, Gali, Adam, additional, De Feudis, Mary, additional, Ngandeu Ngambou, Midrel Wilfried, additional, Achard, Jocelyn, additional, Tallaire, Alexandre, additional, Schmidt, Martin, additional, Becher, Christoph, additional, and Roch, Jean-François, additional

Published

2022

11. Combined synchrotron x-ray diffraction and NV diamond magnetic microscopy measurements at high pressure

Author

Toraille, Loïc, primary, Hilberer, Antoine, additional, Plisson, Thomas, additional, Lesik, Margarita, additional, Chipaux, Mayeul, additional, Vindolet, Baptiste, additional, Pépin, Charles, additional, Occelli, Florent, additional, Schmidt, Martin, additional, Debuisschert, Thierry, additional, Guignot, Nicolas, additional, Itié, Jean-Paul, additional, Loubeyre, Paul, additional, and Roch, Jean-François, additional

Published

2020

12. Utilisation de centres NV comme capteurs de champs magnétiques à haute pression dans des cellules à enclumes de diamant

Author

Toraille, Loïc, Laboratoire Aimé Cotton (LAC), École normale supérieure - Cachan (ENS Cachan)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Université Paris Saclay (COmUE), Jean-François Roch, and Thierry Debuisschert

Subjects

Diamond anvil cell, High pressure, Centre NV, [PHYS.PHYS]Physics [physics]/Physics [physics], Cellule à enclumes de diamant, Magnetometry, NV center, Haute pression, Magnétométrie

Abstract

Pressure is a physical variable that alters structural, electronic and magnetic interactions in all materials. Reaching high pressure is thus a way to create new materials such as superconductors with record critical temperatures. High pressures can be enabled through the use of diamond anvil cells (DAC), which can attain pressures of several hundred of GPa. It is however quite a challenge to measure magnetic properties of materials inside a DAC because of the very small sample volume available and of technical constraints. In this PhD thesis, we demonstrate the use of a magnetometry method based on the electronic spin resonance of NV centers in diamond. These NV centers are fabricated directly on top of one of the DAC anvils, which places them in contact with the magnetic sample.In the first chapter, we describe how the DAC works and we present the different ways of probing magnetic properties that have been developed for high pressure conditions. We then explain the operating principle of NV magnetometry and use this method to measure the magnetization of a micro-magnet at ambient pressure. The sensitivity of this measure is comparable to that of SQUID magnetometry. In the third chapter, we discuss how mechanical constraints modify the spin resonance of the NV center, and describe how this effect combines with the influence of an external magnetic field. By decoupling these two effects, we can observe the magnetic phase transition of iron around 15 to 30 GPa, which is displayed in the fourth chapter. Finally, the last chapter briefly presents the context and stakes associated with the synthesis of superconducting superhydrides with high critical temperature. We perform an optical detection of a superconducting phase inside a DAC with NV centers through the observation of the Meissner effect in MgB2 at a pressure of 7 GPa and with a critical temperature of 30 K.; La pression est un paramètre physique qui modifie les interactions structurales, électroniques et magnétiques dans les matériaux. Créer une très haute pression permet donc la synthèse de nouveaux matériaux, comme par exemple des supraconducteurs ayant des valeurs de température critique record. Ces pressions peuvent être générées au moyen d’une cellule à enclume de diamant (DAC) qui peut comprimer un matériau jusqu’à des pressions de plusieurs centaines de GPa. Il est cependant difficile de caractériser les propriétés magnétiques de matériaux à l’intérieur d’une DAC à cause du très faible volume occupé par l’échantillon et des contraintes techniques. Dans cette thèse, nous proposons d’utiliser une technique de magnétométrie optique fondée sur la résonance de spin électronique de centres colorés NV du diamant. Ces centres NV sont fabriqués à la surface d’une des deux enclumes de la DAC et sont ainsi au contact de l’échantillon magnétique à caractériser.Dans un premier chapitre, nous rappelons le fonctionnement de la DAC et décrivons les techniques de mesures magnétiques développées pour la physique des hautes pressions. Nous présentons ensuite le principe de la magnétométrie à centres NV et l’appliquons à la mesure de l’aimantation d’un micro-aimant à pression ambiante. La sensibilité de cette mesure atteint celle des magnétomètres à SQUID. Le troisième chapitre discute de la façon dont les contraintes mécaniques modifient la résonance de spin du centre NV, et détaille la manière dont cet effet se combine avec celui dû à un champ magnétique externe. La possibilité de découpler les deux effets nous permet d’observer la transition de phase magnétique du fer autour de 15 à 30 GPa dans le quatrième chapitre. Enfin, le dernier chapitre décrit le contexte et les enjeux liés à la synthèse d’hydrures supraconducteurs à haute température critique. Nous montrons ensuite qu’il est possible de détecter optiquement une phase supraconductrice à l’intérieur d’une DAC en utilisant les centres NV pour observer l’effet Meissner de MgB2 à une pression de 7 GPa et avec une température critique de 30 K.

Published

2019

13. Using NV centers as high-pressure magnetic sensors inside diamond anvil cells

Author

Toraille, Loïc, Laboratoire Aimé Cotton (LAC), École normale supérieure - Cachan (ENS Cachan)-Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), Université Paris Saclay (COmUE), Jean-François Roch, and Thierry Debuisschert

Subjects

Diamond anvil cell, High pressure, Centre NV, [PHYS.PHYS]Physics [physics]/Physics [physics], Cellule à enclumes de diamant, Magnetometry, NV center, Haute pression, Magnétométrie

Abstract

Pressure is a physical variable that alters structural, electronic and magnetic interactions in all materials. Reaching high pressure is thus a way to create new materials such as superconductors with record critical temperatures. High pressures can be enabled through the use of diamond anvil cells (DAC), which can attain pressures of several hundred of GPa. It is however quite a challenge to measure magnetic properties of materials inside a DAC because of the very small sample volume available and of technical constraints. In this PhD thesis, we demonstrate the use of a magnetometry method based on the electronic spin resonance of NV centers in diamond. These NV centers are fabricated directly on top of one of the DAC anvils, which places them in contact with the magnetic sample.In the first chapter, we describe how the DAC works and we present the different ways of probing magnetic properties that have been developed for high pressure conditions. We then explain the operating principle of NV magnetometry and use this method to measure the magnetization of a micro-magnet at ambient pressure. The sensitivity of this measure is comparable to that of SQUID magnetometry. In the third chapter, we discuss how mechanical constraints modify the spin resonance of the NV center, and describe how this effect combines with the influence of an external magnetic field. By decoupling these two effects, we can observe the magnetic phase transition of iron around 15 to 30 GPa, which is displayed in the fourth chapter. Finally, the last chapter briefly presents the context and stakes associated with the synthesis of superconducting superhydrides with high critical temperature. We perform an optical detection of a superconducting phase inside a DAC with NV centers through the observation of the Meissner effect in MgB2 at a pressure of 7 GPa and with a critical temperature of 30 K.; La pression est un paramètre physique qui modifie les interactions structurales, électroniques et magnétiques dans les matériaux. Créer une très haute pression permet donc la synthèse de nouveaux matériaux, comme par exemple des supraconducteurs ayant des valeurs de température critique record. Ces pressions peuvent être générées au moyen d’une cellule à enclume de diamant (DAC) qui peut comprimer un matériau jusqu’à des pressions de plusieurs centaines de GPa. Il est cependant difficile de caractériser les propriétés magnétiques de matériaux à l’intérieur d’une DAC à cause du très faible volume occupé par l’échantillon et des contraintes techniques. Dans cette thèse, nous proposons d’utiliser une technique de magnétométrie optique fondée sur la résonance de spin électronique de centres colorés NV du diamant. Ces centres NV sont fabriqués à la surface d’une des deux enclumes de la DAC et sont ainsi au contact de l’échantillon magnétique à caractériser.Dans un premier chapitre, nous rappelons le fonctionnement de la DAC et décrivons les techniques de mesures magnétiques développées pour la physique des hautes pressions. Nous présentons ensuite le principe de la magnétométrie à centres NV et l’appliquons à la mesure de l’aimantation d’un micro-aimant à pression ambiante. La sensibilité de cette mesure atteint celle des magnétomètres à SQUID. Le troisième chapitre discute de la façon dont les contraintes mécaniques modifient la résonance de spin du centre NV, et détaille la manière dont cet effet se combine avec celui dû à un champ magnétique externe. La possibilité de découpler les deux effets nous permet d’observer la transition de phase magnétique du fer autour de 15 à 30 GPa dans le quatrième chapitre. Enfin, le dernier chapitre décrit le contexte et les enjeux liés à la synthèse d’hydrures supraconducteurs à haute température critique. Nous montrons ensuite qu’il est possible de détecter optiquement une phase supraconductrice à l’intérieur d’une DAC en utilisant les centres NV pour observer l’effet Meissner de MgB2 à une pression de 7 GPa et avec une température critique de 30 K.

Published

2019

14. Optical Magnetometry of Single Biocompatible Micromagnets for Quantitative Magnetogenetic and Magnetomechanical Assays

Author

Toraille, Loïc, primary, Aïzel, Koceila, additional, Balloul, Élie, additional, Vicario, Chiara, additional, Monzel, Cornelia, additional, Coppey, Mathieu, additional, Secret, Emilie, additional, Siaugue, Jean-Michel, additional, Sampaio, João, additional, Rohart, Stanislas, additional, Vernier, Nicolas, additional, Bonnemay, Louise, additional, Debuisschert, Thierry, additional, Rondin, Loïc, additional, Roch, Jean-François, additional, and Dahan, Maxime, additional

Published

2018

15. Micro Magnetic Arrays for Micromanipulation at the Molecular and Cellular Scale

Author

Aizel, Koceila, primary, VIichario, Chiara, additional, Balloul, Elie, additional, Monzel, Cornelia, additional, Secret, Emilie, additional, Toraille, Loïc, additional, Coppey, Mathieu, additional, and Dahan, Maxime, additional

Published

2018