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BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260519T140000
DTEND;TZID=Europe/Paris:20260519T150000
DTSTAMP:20260618T011435
CREATED:20260507T131427Z
LAST-MODIFIED:20260507T131427Z
UID:10000151-1779199200-1779202800@sfp-alpes.fr
SUMMARY:Oded ZILBERBERG (University of Konstanz)
DESCRIPTION:Entanglement-based observables for quantum impurities\nRésumé : \nQuantum impurities exhibit fascinating many-body phenomena when the small interacting impurity changes the physics of a large noninteracting environment. The characterisation of such strongly correlated nonperturbative effects is particularly challenging due to the infinite size of the environment\, and the inability of local correlators to capture the buildup of long-ranged entanglement in the system. Here\, we harness an entanglement-based observable—the purity of the impurity—as a witness for the formation of strong correlations. We showcase the utility of our scheme by exactly solving the open Kondo box model in the small box limit\, and thus describe all-electronic dot-cavity devices. Specifically\, we conclusively characterize the metal-to-insulator phase transition in the system and identify how the (conducting) dot-lead Kondo singlet is quenched by an (insulating) intraimpurity singlet formation. Furthermore\, we propose an experimentally feasible tomography protocol for the measurement of the purity\, which motivates the observation of impurity physics through their entanglement build up. \n– \nContact : simon.zihlmann@cea.fr
URL:https://sfp-alpes.fr/event/oded-zilberberg-university-of-konstanz/
LOCATION:CNRS – Salle Rémy Lemaire (K223)\, CNRS - Institut Néel 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260519T140000
DTEND;TZID=Europe/Paris:20260519T150000
DTSTAMP:20260618T011435
CREATED:20260424T125744Z
LAST-MODIFIED:20260424T125744Z
UID:10000134-1779199200-1779202800@sfp-alpes.fr
SUMMARY:Arnaud CLAUDEL (CNRS - Institut Néel)
DESCRIPTION:Growth of graphene by CVD and transfer on various substrates\nRésumé : \nGraphene is a monolayer of sp² carbon atoms which forms a stable\, continuous and gas-impermeable membrane. It also exhibits several exceptional properties (electrical conductivity\, optical transparency\, …)\, making it a candidate of interest for various research topics and applications (transparent electrodes\, detection of chemical or biochemical compounds\, …). Since its discovery in 2004\, graphene has paved the way for two-dimensional (2D) materials\, which are currently the subject of extensive research. For over 15 years\, Institut Néel has been developing and optimising processes for the growth of graphene by chemical vapour deposition (CVD) as well as for transferring these layers onto foreign substrates for a wide range of fundamental and applied research projects. Graphene growth process by CVD and the different forms of graphene (monolayers\, multilayers\, single crystals\, …) will be described. Graphene transfer onto different types of materials will be presented in the frame of various research projects. \nShort Bio/CV \nArnaud CLAUDEL has a MSc (2006) and PhD (2009) in materials science and engineering from Grenoble INP. With 20 years of R&D experience in materials science\, he has been previously R&D project manager in both a company (ACERDE SAS – 2006-2012) and research institutes (CEA-LITEN – 2012-2013\, LMGP – 2014-2015) within fundamental and applicative research projects with academic and industrial partners. Since 2016\, he is CNRS research engineer and since 2021\, manager of the Epitaxial and thin layers (EpiCM) technological group at Institut Néel. His research activities are dedicated to processes for growing epitaxial and thin layers and are mainly focused on the growth and transfer of graphene layers since 2019. \n_ \nContact : deborah.verger@grenoble-inp.fr
URL:https://sfp-alpes.fr/event/arnaud-claudel-cnrs-institut-neel/
LOCATION:LMGP – salle des séminaires\, Grenoble INP -Phelma 3 parvis Louis Néel\, Grenoble\, 38054\, France
CATEGORIES:Séminaire
ORGANIZER;CN="LMGP":MAILTO:deborah.verger@grenoble-inp.fr
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260521T140000
DTEND;TZID=Europe/Paris:20260521T150000
DTSTAMP:20260618T011435
CREATED:20260424T131420Z
LAST-MODIFIED:20260424T131442Z
UID:10000135-1779372000-1779375600@sfp-alpes.fr
SUMMARY:Julien GABELLI (LPS\, Université Paris-Saclay)
DESCRIPTION:Direct Surface Plasmon Detection using Kinetic Inductance Detectors\nRésumé : \nWe present a new kind of on-chip surface plasmon polariton (SPP) detector based on kinetic inductance detectors (KIDs). Our device combines a hybrid NbTiN-Al microwave resonators architecture\, where aluminum serves not only as a photon absorber but also as a plasmonic material. The characteristics of this new detector are demonstrated by detecting optically excited surface plasmon polaritons (SPPs) at a wavelength of 1.5 µm. Notably\, our detector enables direct observation of quasiparticle diffusion in aluminum\, providing new insights into non-equilibrium dynamics at the nanoscale. By detecting SPPs from inelastic tunneling in Al/Al₂O₃/Al junctions\, this work opens new approaches for probing current fluctuations at optical frequencies. \n_ \nContact : florence.levy-bertrand@neel.cnrs.fr  \n 
URL:https://sfp-alpes.fr/event/julien-gabelli-lps-universite-paris-saclay/
LOCATION:CNRS – Salle Rémy Lemaire (K223)\, CNRS - Institut Néel 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260521T150000
DTEND;TZID=Europe/Paris:20260521T160000
DTSTAMP:20260618T011435
CREATED:20260507T095011Z
LAST-MODIFIED:20260507T095123Z
UID:10000149-1779375600-1779379200@sfp-alpes.fr
SUMMARY:Dorian GUINARD (Maître de conférences en droit public à l'Université Grenoble Alpes (Sciences Po Grenoble))
DESCRIPTION:La protection de la biodiversité par le droit\nRésumé : \nLe droit de l’environnement comporte un certain nombre de normes qui théoriquement protègent la biodiversité. L’étude de certains contentieux\, notamment ceux des pesticides et des espèces protégées\, amènent à nuancer ce constat en soulignant les lacunes juridiques\, les enjeux\, et le rôle des juges et de la société civile. \nAttention ! L’accès au site du CNRS est contrôlé. Munissez-vous de votre badge ou contactez Yvonne Soldo (yvonne.soldo@neel.cnrs.fr) suffisamment à l’avance pour accéder au site. \n_ \nContact : julien.delahaye@neel.cnrs.fr
URL:https://sfp-alpes.fr/event/dorian-guinard-maitre-de-conferences-en-droit-public-a-luniversite-grenoble-alpes-sciences-po-grenoble/
LOCATION:CNRS – Bâtiment A\, CNRS - Institut Néel 25 avenue des Martyrs\, Grenoble\, 38054\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260522T110000
DTEND;TZID=Europe/Paris:20260522T120000
DTSTAMP:20260618T011435
CREATED:20260521T143647Z
LAST-MODIFIED:20260521T143647Z
UID:10000156-1779447600-1779451200@sfp-alpes.fr
SUMMARY:Vladimir ZAKHAROV (Leiden University)
DESCRIPTION:Luttinger liquid and mass generation on a lattice\nRésumé : \nThe helical edge of a quantum spin Hall insulator hosts a one-dimensional metallic state with spin-momentum locking\, realizing a helical Luttinger liquid (HLL). While the gapless phase is well understood analytically through bosonization in its simplest form\, more complex questions that demand numerical treatment\, have remained largely inaccessible to address for a long time. The core obstacle is the fermion-doubling problem: any local and symmetry-preserving discretization of the Hamiltonian on a strictly one-dimensional lattice either introduces spurious low-energy modes or lifts the Dirac point\, breaking the topological protection of the cone.\nIn this talk I describe how this obstruction can be circumvented using a tangent fermion discretization. This preserves time-reversal symmetry and spin-momentum locking at the lattice level\, without invoking a two-dimensional bulk. I present the application of this method first to the gapless HLL\, where numerical results are in quantitative agreement with bosonization predictions\, establishing the framework as a reliable numerical tool. And then I turn to interaction-induced mass generation\, including spontaneous time-reversal symmetry breaking in HLL and symmetric mass generation in 3-4-5-0 model\, where full analytical treatment is out of reach. \n_ \nContact : serge.florens@neel.cnrs.fr
URL:https://sfp-alpes.fr/event/vladimir-zakharov-leiden-university/
LOCATION:LPMMC – salle Roger Maynard (G421)\, CNRS - LPMMC 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260526T140000
DTEND;TZID=Europe/Paris:20260526T150000
DTSTAMP:20260618T011435
CREATED:20260521T142155Z
LAST-MODIFIED:20260521T142155Z
UID:10000155-1779804000-1779807600@sfp-alpes.fr
SUMMARY:Jamie SILK (PhD Student - LMGP\, Université Grenoble Alpes\, CNRS\, Grenoble INP\, Grenoble\, France)
DESCRIPTION:Development of a Sustainable Passive Atmospheric Water Harvesting Device\nRésumé : \nWater is essential for human life\, yet roughly two billion people worldwide still lack access to safely managed drinking water. With increasing pressure from rapid population growth and climate change\, there is a critical need for water generation technologies that are low-cost\, scalable\, and environmentally sustainable. Passive atmospheric water harvesting offers a promising solution by capturing moisture from the air without continuous energy input\, but current approaches are often limited by low efficiency or high cost. This study aims to optimize a bioinspired mixed-wettability surface to enhance passive water collection by promoting both droplet nucleation and rapid transport of condensed water. The surface is fabricated using superhydrophobic zinc oxide nanowire (NW) arrays synthesized via a scalable sol-gel/chemical bath deposition method\, followed by functionalization with a non-fluorinated silane agent. Hydrophilic silica nanoparticles are then deposited on the superhydrophobic NW arrays to create the mixed wettability effect. Material performance is optimized by varying NW morphology\, surface wettability\, and nanoparticle concentration to maximize water collection rates. To induce condensation without energy input\, this mixed-wettability surface is coupled with a passive daytime radiative cooling (PDRC) coating composed of bicontinuous interfacially jammed emulsion gels (bijels). These porous polymer films exhibit high solar reflectance and strong infrared emissivity\, enabling sub-ambient cooling. The PDRC layer is optimized by adjusting domain size and film thickness to achieve maximum cooling performance. In parallel\, a life cycle assessment (LCA) is conducted to evaluate the environmental impacts of material fabrication and identify key contributors to categories such as global warming potential\, water use\, and ozone depletion. This integrated approach informs design choices that minimize environmental burden. The results of this study show promise in developing a material with the ability to passively collect atmospheric water even in climates with low levels of humidity\, potentially aiding in providing clean water globally in the face of the climate crisis. \nShort Bio/CV \nI am a PhD student at the LMGP lab studying passive atmospheric water harvesting technologies. I hold a Bachelor’s degree in Chemical Engineering and a Master’s degree in Sustainable Engineering for International Development from Villanova University (Pennsylvania\, USA). During my master’s\, my research studied the impact of climate change on drinking water resources in Madagascar\, combining data from the latest IPCC climate models with local stakeholder knowledge and priorities to plan for future climate-related water challenges. In 2025\, I spent four months as an invited researcher at the SMART LAB at the University of Pennsylvania\, where I researched passive daytime radiative cooling coatings. My current research builds on this background\, focusing on the development of environmentally sustainable\, low-cost\, scalable materials for passive water collection. \n_ \nContact : deborah.verger@grenoble-inp.fr
URL:https://sfp-alpes.fr/event/jamie-silk-phd-student-lmgp-universite-grenoble-alpes-cnrs-grenoble-inp-grenoble-france/
LOCATION:LMGP – salle des séminaires\, Grenoble INP -Phelma 3 parvis Louis Néel\, Grenoble\, 38054\, France
CATEGORIES:Séminaire
ORGANIZER;CN="LMGP":MAILTO:deborah.verger@grenoble-inp.fr
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260527T090000
DTEND;TZID=Europe/Paris:20260529T170000
DTSTAMP:20260618T011435
CREATED:20260305T155829Z
LAST-MODIFIED:20260305T160317Z
UID:10000095-1779872400-1780074000@sfp-alpes.fr
SUMMARY:Mag2Pol MasterClass
DESCRIPTION:We are pleased to announce the first Mag2Pol MasterClass\, an advanced course dedicated to diffraction data analysis using X-ray and (polarised) neutron data from powders and single-crystals. \nThe MasterClass will take place at the Institut Laue-Langevin (ILL) in Grenoble\, France. It is aimed at both early-career and experienced researchers\, and will combine focused lectures with hands-on tutorials. Particular emphasis will be placed on magnetic structure determination and symmetry analysis using Mag2Pol. \nTo ensure high pedagogical quality and close interaction between participants and instructors\, attendance will be limited to 30 participants. Selection will be based on a short CV and a brief statement of motivation. Please submit your applications before 15 March 2026. \nFull details\, including important dates\, registration information\, and a tentative program\, are available here : https://workshops.ill.fr/e/Mag2Pol \nFor any questions\, please contact us at : mag2pol@ill.fr
URL:https://sfp-alpes.fr/event/mag2pol-masterclass/
LOCATION:ILL – Salle de Séminaire (110-111)\, ILL 50 71 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Workshop
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260527T140000
DTEND;TZID=Europe/Paris:20260527T160000
DTSTAMP:20260618T011435
CREATED:20260424T084229Z
LAST-MODIFIED:20260430T125033Z
UID:10000131-1779890400-1779897600@sfp-alpes.fr
SUMMARY:Soutenance de Thèse de Thomas BRUN (IRIG / Spintec)
DESCRIPTION:MAROT : Un magnétomètre miniature pour l’exploration spatiale\nRésumé : \nCette thèse porte sur la réalisation d’un magnétomètre dans le but de mesurer les fluctuations de champ magnétique dans les plasmas spatiaux du système solaire. Des magnétomètres de type Search-coil et Fluxgate sont couramment embarqués sur des satellites et produisent des mesures de haute qualité. De nos jours\, la recherche utilise de plus en plus de petits satellites dont l’archétype est le « Cubsat » qui est un cube de 10 cm de côté. Cependant\, l’instrumentation actuelle ne peut pas être miniaturisée sans compromettre les performances. C’est dans ce cadre que le projet MAROT propose l’élaboration d’un magnétomètre miniature utilisant comme élément sensible des jonctions tunnel magnétiques (MTJ)\, pour mesurer des champs de l’ordre du picotesla. Les jonctions tunnel magnétiques sont des éléments convertissant une variation d’aimantation en variation de résistance\, permettant ainsi de mesurer les variations de champ magnétique. Ces magnétomètres sont déjà utilisés comme capteurs dans de nombreuses applications (automobile\, imagerie médicale\, capteurs dans des systèmes électroniques…) de par leur haute sensibilité au champ magnétique. Cependant\, les MTJ souffrent d’une perte de détectivité à basse fréquence car leur bruit évolue inversement à la fréquence du signal mesuré. Or les basses fréquences (< 100 Hz) sont les fréquences pertinentes pour les plasmas spatiaux. Pour compenser cette limitation\, le capteur MAROT contient des concentrateurs de flux (FC) pour amplifier le champ magnétique sur la jonction. L’optimisation du capteur passe d’une part par l’augmentation de sa sensibilité et d’autre part par la diminution du bruit\, afin d’atteindre une détectivité de l’ordre du pT/√Hz à 10 Hz. Les jonctions tunnels sont constituées d’un empilement constitué de plusieurs blocs : couche de référence\, barrière tunnel\, couche libre. Dans ma thèse\, j’ai utilisé et réalisé des jonctions tunnels à réponse symétrique\, présentant un état antiparallèle à champ nul\, obtenu après un recuit sous champ. Cet état\, ainsi que la configuration macrospin de la couche libre\, minimisant l’hystérèse\, est réalisée en piégeant légèrement la couche libre par une couche antiferromagnétique. Lors de cette thèse\, tout d’abord\, j’ai pu avoir accès à une couche libre à base de FeCoSiB\, couche plus amorphe et plus douce que le NiFe précédemment utilisé\, permettant une amélioration du rapport de magnétorésistance (TMR) d’un facteur supérieur à 2\, jusqu’à 250%. Ces optimisations ont permis de gagner un facteur 3 dans la sensibilité des jonctions. Dans un second temps\, j’ai réalisé des simulations de l’amplification du champ magnétique par les concentrateurs de flux (gain) en fonction des dimensions et caractéristiques de l’entrefer. Cette étude m’a permis de dessiner un nouveau design de capteur dans lequel des jonctions en série-parallèle sont ajoutées dans l’entrefer afin d’augmenter le volume magnétique\, pour réduire le bruit\, tout en maintenant un gain suffisant. Des capteurs avec ce design ont été fabriqués. Les premières mesures indiquent des sensibilités très grandes\, de l’ordre de 2000 %/mT. Les mesures de bruit sont en cours\, et semblent indiquer que les FC\, à base de NiFe déposés par électrolyse\, apportent du bruit supplémentaire. La composition de ces FC sera donc à optimiser afin d’améliorer la détectivité\, actuellement autour de quelques centaines de pT/√Hz à 10 Hz. Pour finir\, j’ai commencé à développer une méthode de hachage de champ magnétique pour réduire le bruit. Une couche magnétostrictive\, déposée sur un substrat piézoélectrique soumis à une tension\, peut voir sa direction d’anisotropie modifiée. Ce dispositif pourra être placé au-dessus de l’entrefer des FC et utilisé comme un interrupteur magnétique\, qui alternativement modifie le flux magnétique sur les jonctions. Un gain d’un facteur au moins 10 sur la détectivité est attendu\, ce qui permettra de s’approcher de l’objectif du pT/√Hz à 10 Hz. \nPlus d’information :https://www.spintec.fr/phd-defense-marot-a-miniature-magnetometer-for-space-exploration/ \nPour suivre la soutenance ​​​en visioconférence : https://univ-grenoble-alpes-fr.zoom.us/j/98769867024 \n_ \n\n\nP​resential access to the conference room at CEA in Gre​​noble requires an entry authorization\, request it before may 16th​​ to admin.spintec@cea.fr
URL:https://sfp-alpes.fr/event/thomas-brun-irig-spintec/
LOCATION:CEA – Salle de Séminaire IRIG (1005 – 445)\, Laboratoire Irig/Spintec\, salle de séminaire 445\, bâtiment 1005\, CEA-Grenoble\, Grenoble
CATEGORIES:Soutenance,Soutenance de Thèse
ORGANIZER;CN="IRIG - CEA":MAILTO:odile.rossignol@cea.fr
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260528T140000
DTEND;TZID=Europe/Paris:20260528T150000
DTSTAMP:20260618T011435
CREATED:20260430T121134Z
LAST-MODIFIED:20260430T122107Z
UID:10000139-1779976800-1779980400@sfp-alpes.fr
SUMMARY:Alexandre BUZDIN (LOMA\, Bordeaux)
DESCRIPTION:Optical and TeraHertz radiation methods of flux manipulation in superconductors\nRésumé : \nAlthough the average properties of vortex matter in superconductors can be tuned using magnetic fields\, temperature\, or electric currents\, the manipulation of individual Abrikosov vortices remains challenging and has only been demonstrated with advanced scanning local probe microscopies. Recently\, a far-field optical method was proposed\, leveraging local heating of the superconductor with a focused laser beam to enable fast and precise manipulation of individual vortices\, akin to optical tweezers. This development paves the way for creating laser-driven Josephson junctions controlled by optically driven Abrikosov vortices. \nAnother approach for manipulating single flux quanta involves the so-called inverse Faraday effect\, where circularly polarized radiation interacts with the superconducting condensate\, acting as an effective magnetic field that generates supercurrents and DC magnetic moments. By employing the time-dependent Ginzburg–Landau equation formalism\, we have analyzed the current-carrying states of a small superconducting ring illuminated by such radiation. Numerical simulations reveal the possibility of 100% on-demand switching between current-carrying states in the superconductor by controlling the helicity of the electromagnetic field polarization. \nFurthermore\, theoretical analysis suggests the feasibility of the electromagnetic drag effect in superconductors—the generation of DC supercurrents and second harmonic signals induced by microwave radiation incident on a superconducting surface. \nThese findings open pathways to the all-optical operation of superconducting devices\, including RF SQUID flux qubits. \n_ \nContact : florence.levy-bertrand@neel.cnrs.fr
URL:https://sfp-alpes.fr/event/alexandre-buzdin-loma-bordeaux/
LOCATION:CNRS – Salle Rémy Lemaire (K223)\, CNRS - Institut Néel 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260529T110000
DTEND;TZID=Europe/Paris:20260529T120000
DTSTAMP:20260618T011435
CREATED:20260521T141533Z
LAST-MODIFIED:20260521T143851Z
UID:10000154-1780052400-1780056000@sfp-alpes.fr
SUMMARY:Gilles PAREZ
DESCRIPTION:The range of multipartite entanglement in many-body states\nLe séminaire théorie est financé par la fédération de recherche Quantalps \nRésumé : \nThe characterization of entanglement and its structure in quantum many-body states is a long-standing problem at the interface of condensed matter physics and quantum information. A pivotal question is to understand to what extent two or more regions can remain entangled at large distances. As it turns out\, this is more subtle than understanding the range of quantum correlations: strongly correlated states such as resonating valence-bond states and critical ground states can display long-range correlations but only short-range multipartite entanglement. I will discuss how particle statistics and superselection rules also play a role in this problem\, and how to understand it within the broader “fate of entanglement” framework\, which goes beyond the study of entanglement decay with distance and also applies to finite-temperature systems and nonequilibrium dynamics. \n_ \nContact : jeanne.colbois@neel.cnrs.fr \n 
URL:https://sfp-alpes.fr/event/gilles-parez/
LOCATION:LPMMC – salle Roger Maynard (G421)\, CNRS - LPMMC 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260602T140000
DTEND;TZID=Europe/Paris:20260602T150000
DTSTAMP:20260618T011435
CREATED:20260528T154225Z
LAST-MODIFIED:20260528T154225Z
UID:10000164-1780408800-1780412400@sfp-alpes.fr
SUMMARY:Marielena VELASCO-ENRIQUEZ (LMGP\, Institut Néel)
DESCRIPTION:Chemical pathways to obtain Ga2O3 films for next generation power electronics and optoelectronics\nRésumé : \nUltrawide bandgap semiconductors like β-Ga2O3 are promising candidates for power electronics and optoelectronics thanks to their large bandgap energy (4.6 – 4.9 eV)\, high breakdown electric field (~8 MV/cm)\, broadband photodetection\, and availability of high-quality substrates.[1] Beyond the thermodynamically stable β-Ga2O3\, metastable polymorphs (α\, γ\, δ\, κ) may offer additional functionalities\, including piezoelectricity (κ-phase).[2] \nThis work explores two different chemical approaches in vapor phase and aqueous solution to grow Ga₂O₃ thin films and microstructures on c-plane sapphire substrates. First\, pulsed-liquid injection MOCVD (PLI-MOCVD)\, that unlike conventional MOCVD systems\, enables fine control over precursor delivery and dosing\, improving chemical yield and reducing gallium waste\, an important sustainability consideration.[3] Second\, chemical bath deposition (CBD) followed by thermal annealing that offers a low-cost\, tunable pathway to obtain crystalline Ga₂O₃\,[4] though the link between growth parameters and final properties remains poorly understood. \nBy adapting and systematically investigating both methods\, the impact of key parameters on morphology\, structure\, chemistry\, and optical properties using a broad range of characterization techniques (SEM\, XRD\, TEM\, XPS\, Raman\, UV-Vis\, cathodoluminescence\, etc.) is studied. This comparative approach provides insight into the assets and limitations of each technique for controlled Ga₂O₃ synthesis. \n[1]        J. Y. Tsao et al.\, “Ultrawide-Bandgap Semiconductors: Research Opportunities and Challenges\,” Advanced Electronic Materials\, vol. 4\, no. 1\, p. 1600501\, 2018\, doi: 10.1002/aelm.201600501. \n[2]        M. Bosi\, P. Mazzolini\, L. Seravalli\, and R. Fornari\, “Ga 2 O 3 polymorphs: tailoring the epitaxial growth conditions\,” Journal of Materials Chemistry C\, vol. 8\, no. 32\, pp. 10975–10992\, 2020\, doi: 10.1039/D0TC02743J. \n[3]        H. Guillon and S. Bonnafous\, “Vaporization of Solid or Liquid Organic\, Organometallic or Inorganic Compounds\,” no. Gases&Instrumentation\, pp. 17–19\, Jun. 2008. \n[4]        G. Hector et al.\, “Chemical Synthesis of β-Ga2O3 Microrods on Silicon and Its Dependence on the Gallium Nitrate Concentration\,” Inorg. Chem.\, vol. 59\, no. 21\, pp. 15696–15706\, Nov. 2020\, doi: 10.1021/acs.inorgchem.0c02069. \nShort Bio/CV \nOriginally from the Amazonian region of Peru. I earned my Bachelor’s in Engineering physics at Universidad Nacional de Ingeniería in Lima\, Peru. After conducting research in Peru and abroad on soft robotics\, plasma physics\, and material science\, I moved into industry as an R&D Engineer in the automotive sector\, designing and testing eGlasses. Three years later\, I pursued the Erasmus Mundus Master in Nanoscience and Nanotechnology\, specializing in nanoelectronics at KU Leuven (Belgium) and TU Dresden (Germany). Since 2023\, I have been a PhD candidate at Université Grenoble Alpes\, working across LMGP and Institut Néel as part of the cross-disciplinary program PowerAlps from. \n_ \nContact : deborah.verger@grenoble-inp.fr 
URL:https://sfp-alpes.fr/event/marielena-velasco-enriquez-lmgp-institut-neel/
LOCATION:LMGP – salle des séminaires\, Grenoble INP -Phelma 3 parvis Louis Néel\, Grenoble\, 38054\, France
CATEGORIES:Séminaire
ORGANIZER;CN="LMGP":MAILTO:deborah.verger@grenoble-inp.fr
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260602T150000
DTEND;TZID=Europe/Paris:20260602T160000
DTSTAMP:20260618T011435
CREATED:20260529T085706Z
LAST-MODIFIED:20260529T085706Z
UID:10000166-1780412400-1780416000@sfp-alpes.fr
SUMMARY:Christophe VALLEE (College of Nanotechnology\, Science\, and Engineering (CNSE) - University at Albany - SUNY)
DESCRIPTION:Le dépôt sélectif par zone (ASD) : de la substitution de la lithographie à son amélioration\nRésumé : \nDans cet exposé\, nous allons présenter le dépôt sélectif par zone (Area Selective Deposition) et illustrer le fait que ce procédé\, initialement développé pour supprimer des étapes de lithographie\, peut être aussi utilisé pour améliorer ces étapes. \nDans un premier temps\, nous introduirons les différentes façons de faire un dépôt sélectif par zone\, puis nous donnerons quelques exemples d’application. Ensuite\, nous discuterons des interactions entre ce procédé et des matériaux polymères afin de démontrer que les polymères peuvent être utilisés comme inhibiteurs dans un procédé ASD. De plus\, nous montrerons que le procédé ASD peut aussi être réalisé directement sur des polymères\, pour améliorer certaines de leurs propriétés telles que leur rugosité de surface et leur résistance à la gravure plasma. Nous finirons en donnant un exemple de dépôt sélectif « vertical » combinant à la fois une gravure sélective du polymère par effet catalytique et un dépôt sélectif par zone. \nShort Bio/CV \nChristophe Vallée est professeur à l’Université Grenoble Alpes jusqu’en 2020\, spécialisé dans les procédés plasma. Il a mené ses recherches au Laboratoire des Technologies de la Microélectronique (LTM) – Polytech Grenoble\, ainsi qu’en tant que professeur invité à l’Université de Tsukuba au Japon (2016–2020). En 2020\, il y a été nommé premier «TEL Innovation Scientist»\, soutenu par une dotation de 2\,3 millions de dollars pour le développement de technologies avancées au service de l’industrie des semi-conducteurs. Depuis 2022\, il est professeur permanent au CNSE de l’Université d’Albany (État de New York). Ses recherches portent sur la gravure plasma\, le dépôt plasma et les procédés à l’échelle atomique (ALD\, ALE)\, appliqués à la fabrication de dispositifs semi-conducteurs. \n_ \nContact : deborah.verger@grenoble-inp.fr
URL:https://sfp-alpes.fr/event/christophe-vallee-college-of-nanotechnology-science-and-engineering-cnse-university-at-albany-suny/
LOCATION:Phelma minatec\, Salle Z108\, Grenoble INP - Phelma\, 3 parvis Louis Néel\, Grenoble\, 38000\, France
CATEGORIES:Séminaire
ORGANIZER;CN="LMGP":MAILTO:deborah.verger@grenoble-inp.fr
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260603T110000
DTEND;TZID=Europe/Paris:20260603T120000
DTSTAMP:20260618T011435
CREATED:20260529T091746Z
LAST-MODIFIED:20260529T091746Z
UID:10000167-1780484400-1780488000@sfp-alpes.fr
SUMMARY:Arjun DEY (Paul Scherrer Institute)
DESCRIPTION:Excitation energies from ground-state DMRG on the fuzzy sphere\nRésumé : \nIt has been observed that some eigenvalues of the effective local Hamiltonian built during a ground-state DMRG sweep of a one-dimensional critical chain stay nearly flat across iterations. Those flat levels correspond to true low-energy excitations\, giving access to the excitation spectrum at no extra cost. We ask whether the same holds on the fuzzy sphere\, a geometry used to study two-dimensional critical theories by mapping them onto a one-dimensional orbital chain. Getting excited states there directly is costly. We find numerical evidence that flat levels appear in the eigenvalues of the effective local Hamiltonian during our sweeps and match the expected low-energy spectrum. The symmetries of the fuzzy sphere and orthogonalization across symmetry sectors introduce additional structure into those eigenvalues\, which helps in resolving and assigning the excitations. \n_ \nContact : loic.herviou@lpmmc.cnrs.fr
URL:https://sfp-alpes.fr/event/arjun-dey-paul-scherrer-institute/
LOCATION:LPMMC – salle Roger Maynard (G421)\, CNRS - LPMMC 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260604T140000
DTEND;TZID=Europe/Paris:20260604T150000
DTSTAMP:20260618T011435
CREATED:20260528T152555Z
LAST-MODIFIED:20260528T152555Z
UID:10000162-1780581600-1780585200@sfp-alpes.fr
SUMMARY:Nan TANG (University of Augsburg)
DESCRIPTION:New Macroscopic Windows into Spin Ice : From Emergent Monopoles to Quadrupolar Fluctuations\nRésumé : \nSpin ice\, a representative class of frustrated magnets\, provides a rich platform for exploring phenomena such as fractionalized excitations and multipolar degrees of freedom\, which remain difficult to access using conventional magnetic probes. In this seminar\, I will show how thermodynamic measurements\, especially elastic probes\, together with spintronics technique (in particular the spin Seebeck effect)\, can serve as practical detectors of these degrees of freedom. \nI will develop this theme via two studies in the pyrochlore oxides Pr2​Zr2​O7​ and Dy2​Ti2​O7​\, known as spin ices. First\, I will show how bulk thermodynamic measurements\, centered around elastic probes\, can diagnose quantum spin ice physics in Pr2​Zr2​O7​ [1]. Second\, I will discuss how transport-sensitive measurements in an insulator—through the spin Seebeck effect—can access the dynamics of emergent magnetic monopoles in the classical spin ice Dy2​Ti2​O7​ [2]. Together\, these two studies demonstrate how lattice-based probes and spintronic tools can be brought to bear on frustrated magnets\, providing new routes to detect low-energy degrees of freedom. \nIn this way\, precision thermodynamics and modern transport-sensitive techniques can reveal new physics even in long-studied frustrated magnets\, enabling direct comparison with theory through sharp macroscopic signatures. \n[1] N. Tang et al.\, Nat. Phys. 19\, 92-98 (2023).\n[2] N. Tang et al.\, preprint\, arXiv.2509.18422 (2025).\n  \n_ \nContact : elsa.lhotel@neel.cnrs.fr
URL:https://sfp-alpes.fr/event/nan-tang-university-of-augsburg/
LOCATION:CNRS – Salle Rémy Lemaire (K223)\, CNRS - Institut Néel 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260604T160000
DTEND;TZID=Europe/Paris:20260604T170000
DTSTAMP:20260618T011435
CREATED:20260213T142628Z
LAST-MODIFIED:20260213T143322Z
UID:10000071-1780588800-1780592400@sfp-alpes.fr
SUMMARY:Sophie GUERON
DESCRIPTION:Explorer les isolants topologiques avec la physique mésoscopique\n_ \nToutes les informations sont disponibles sur : https://indico.ijclab.in2p3.fr/event/12406/ \nContact : louis.fayard@IJCLAB.INP3.FR
URL:https://sfp-alpes.fr/event/sophie-gueron/
LOCATION:Laboratoire IJCLab – Auditorium Pierre Lehmann\, Rue Ampère\, Orsay cedex\, 91898\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260609T140000
DTEND;TZID=Europe/Paris:20260609T150000
DTSTAMP:20260618T011435
CREATED:20260604T105036Z
LAST-MODIFIED:20260605T084741Z
UID:10000181-1781013600-1781017200@sfp-alpes.fr
SUMMARY:Jean-Claude BESSE (Department of Physics\, ETH Zurich\, CH-8093 Zurich\, Switzerland)
DESCRIPTION:Execution of Blind Quantum Computing Primitives on a Modular Superconducting Processor\nRésumé : \nAs a route towards a cluster of interconnected processors in a quantum network\, the Quantum Device Lab’s approach to short-range modularity uses small modules with high fabrication yield flip-chip bonded to a common carrier chip. In the first part of this talk\, we focus on the hardware realization of this 3D-integrated architecture with indium bump bonds\, inter-chip spacing control\, and parameter targeting enabling high-fidelity operations 1\,2. We then leverage this technology in a two-module processor\, with three qubits per node 3. The first module acts as a server generating cluster states as entangled quantum resource. The second module acts as a client\, consuming the resource through real-time adaptive measurement basis choice. We demonstrate that the client can implement universal single- and two-qubit gates with local measurements and rotations only. As an example of blind quantum computation\, we show results of a measurement-based Deutsch-Jozsa algorithm. We verify that the computation remains private\, that is\, the server’s state doesn’t reveal the client’s algorithm nor its result. This demonstrates that cloud quantum providers can be set up in a way that they respect the data privacy of their clients 4. \n1 Norris et al.\, EPJ Quant. Tech. 11\, 5 (2024) 2 Norris et al.\, EPJ Quant. Tech. 13\, 29 (2026) 3 Dalton et al.\, PRX Quantum 6\, 040365 (2025) 4 Song et al.\, arXiv:2605.14656 (2026) \n_ \nContact : sem_nano_elec_quantique@listes.grenoble.cnrs.fr
URL:https://sfp-alpes.fr/event/jean-claude-besse-department-of-physics-eth-zurich-ch-8093-zurich-switzerland/
LOCATION:CNRS – Salle Rémy Lemaire (K223)\, CNRS - Institut Néel 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260609T140000
DTEND;TZID=Europe/Paris:20260609T150000
DTSTAMP:20260618T011435
CREATED:20260529T080157Z
LAST-MODIFIED:20260529T080157Z
UID:10000165-1781013600-1781017200@sfp-alpes.fr
SUMMARY:Soline BEITONE (PhD Student - LMGP)
DESCRIPTION:Development and evaluation of a photocatalytic system to reduce and valorize CO2\nRésumé : \nThis work focuses on the development of a photocatalytic system for CO₂ reduction and valorization\, contributing to sustainable carbon conversion strategies. The study investigates Cu₂O nanowire (NW)-based photocatalyst\, selected for their visible-light activity\, abundance\, and low toxicity. \nA simple\, scalable\, and cost-effective fabrication strategy was developed to produce such photocatalyst. To enhance performance and stability\, the materials were further engineered through TiO₂ nanoparticle modification\, enabling the formation of p–n heterojunctions that improve charge separation\, stability and light utilization. \nThe resulting photocatalysts were evaluated for CO₂ conversion into value-added products and water depollution through dye degradation. \nFinally\, a life cycle perspective was incorporated to assess environmental impacts\, sustainability benefits\, and the scalability potential of these photocatalytic systems. \nShort Bio/CV \nI am a third-year PhD student with a background in materials science and chemistry. My research focuses on photocatalysis and materials development\, with an emphasis on green and sustainable approaches. \nI am part of the NABIOS team\, and my PhD project is integrated into DéfiCO₂\, a multidisciplinary initiative aimed at developing and evaluating technological solutions for carbon capture and utilization (CCU). \n_ \nContact : deborah.verger@grenoble-inp.fr
URL:https://sfp-alpes.fr/event/soline-beitone-phd-student-lmgp/
LOCATION:LMGP – salle des séminaires\, Grenoble INP -Phelma 3 parvis Louis Néel\, Grenoble\, 38054\, France
CATEGORIES:Séminaire
ORGANIZER;CN="LMGP":MAILTO:deborah.verger@grenoble-inp.fr
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260610T110000
DTEND;TZID=Europe/Paris:20260610T120000
DTSTAMP:20260618T011435
CREATED:20260604T110614Z
LAST-MODIFIED:20260604T110614Z
UID:10000182-1781089200-1781092800@sfp-alpes.fr
SUMMARY:Mahdi ABOU-HAMDAN (LPMMC)
DESCRIPTION:TITRE A VENIR\n_ \nContact : pierre.nataf@lpmmc.cnrs.fr
URL:https://sfp-alpes.fr/event/mahdi-abou-hamdan-lpmmc/
LOCATION:LPMMC – salle Roger Maynard (G421)\, CNRS - LPMMC 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260612T110000
DTEND;TZID=Europe/Paris:20260612T120000
DTSTAMP:20260618T011435
CREATED:20260604T132045Z
LAST-MODIFIED:20260604T132045Z
UID:10000183-1781262000-1781265600@sfp-alpes.fr
SUMMARY:Benjamin LENZ (IMPMC)
DESCRIPTION:Spectroscopic signatures of spin-polarons in quasi two-dimensional correlated materials\nRésumé : \nThe motion of a single hole in a two-dimensional antiferromagnet can lead to the formation of a low-energy quasiparticle\, a so-called spin-polaron\, which amounts to a bound state of the doped hole and a spin flip. In this talk\, I will first introduce the notion of spin-polarons and then discuss spectroscopic signatures of this quasiparticle at the example of two different material classes which both host quasi two-dimensional low-energy physics in their correlated electronic structure.\nIllustrated by the Na-doped oxychloride Ca2CuO2Cl2\, we will see how the spin-polaron gives rise to “kink” and “waterfall” features in the spectral function of hole-doped cuprates. Employing a numerical workflow comprising density functional theory and cluster dynamical mean-field theory\, we will discuss these features in comparison to measurements obtained from angle-resolved photoemission spectroscopy. As a second example\, we will see that spin-polaron physics is also relevant in two prototypical iridates\, (Ba\,Sr)2IrO4\, which host an exotic spin-orbital entangled jeff=1/2 ground state. In particular\, the characteristic two-peak structure of their optical absorption and optical conductivity curves will be revisited and interpreted in the light of these coherent low-energy quasiparticles. \nB. Bacq-Labreuil et al.\, Phys. Rev. Lett. 134\, 016502 (2025)\nF. Cassol et al.\, arXiv:2509.20337; accepted in Phys. Rev. B (2026) \n_ \nContact : serge.florens@neel.cnrs.fr
URL:https://sfp-alpes.fr/event/benjamin-lenz-impmc/
LOCATION:LPMMC – salle Roger Maynard (G421)\, CNRS - LPMMC 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260612T140000
DTEND;TZID=Europe/Paris:20260612T160000
DTSTAMP:20260618T011435
CREATED:20260604T141732Z
LAST-MODIFIED:20260604T141732Z
UID:10000186-1781272800-1781280000@sfp-alpes.fr
SUMMARY:Soutenance de Thèse de Giovanni OLIVETTI (CEA-Irig / Spintec)
DESCRIPTION:Angular Momentum Transfer Between Waveforms in Axisymmetric Geometries\nRésumé : \nThis thesis investigates the role of angular momentum transfer in the coupling between elastic and spin excitations in magneto-mechanical systems. \nIn axisymmetric geometries\, rotational invariance provides the natural framework for the conservation of total angular momentum[1]. In such a case\, this quantity unambiguously labels the eigenmodes of the system and constrains their coupling to an external excitation through well-defined selection rules[2]. The manuscript develops this physical picture from a general perspective based on Noether’s theorem\, it introduces spin and orbital angular momentum contributions for a generic vector field and proposes an analytical description of magneto-elastic coupling in axisymmetric systems. \nThis framework is then applied to two complementary experimental platforms realized in the context of this doctoral work. The first combines chiral surface-acoustic excitations with a magnetic vortex texture in a patterned ferromagnetic disk. The second consists of partially suspended axisymmetric YIG microresonators\, designed to support both low-loss mechanical motion and confined spin dynamics within the same structure[3]. Together\, these two systems provide complementary routes to investigate how elastic and magnetic modes carrying angular momentum can be generated\, controlled\, and coupled in realistic devices. \nIn particular\, this work demonstrates the controlled excitation and optical mapping of a surface-acoustic vortex by means of spiral interdigitated transducers. It further addresses the stabilization of magnetic vortex textures in micrometer-scale ferromagnetic disks on anisotropic piezoelectric substrates\, as well as their positioning at the center of elastic rotation. The coupling strength in suspended axisymmetric YIG microresonators has been evaluated by comparing experimental data with theoretical modeling\, indicating a weak-coupling regime. Moreover\, the role of weak symmetry breaking has been discussed for the selective excitation of counter-propagating elastic modes that would otherwise be degenerate. \nThese developments establish several of the physical and technological conditions required to address experimentally the coupling of elastic and spin excitations carrying angular momentum. More broadly\, they outline a route toward magneto-elastic platforms in which symmetry can be used as a resource for selective excitation. In this perspective\, partially suspended magnetic microresonators may provide a promising route toward strong magnon-phonon coupling under geometrical and symmetry constraints directly relevant for coherent functionalities. In the longer term\, such systems could serve as building blocks for mode-selective transducers and hybrid architectures combining magnetic\, elastic\, and optical degrees of freedom\, with possible perspectives for microwave-to-optical coherent transduction[4]. \nReferences \n\nGaranin & Chudnovsky\, Phys. Rev. B 92\, 024421 (2015).\nAn et al.\, Phys. Rev. B 101\, 060407 (2020).\nHeyroth et al.\, Phys. Rev. Appl. 12\, 054031 (2019).\nEngelhardt et al.\, Phys. Rev. Appl. 18\, 044059 (2022). ​\n\n\n\nPlus d’information\n​ \nPour suivre la soutenance ​​​en visioconférence​ ​​: lien à venir\n\n\n\n\nAccess to the CNRS site is restricted. Please contact Olivetti Giovanni​  or Benjamin Pigeau at least 48h before the defense if you need an entry clearance. You just need to communicate your name and surname\, and you will receive the entry clearance by email.
URL:https://sfp-alpes.fr/event/soutenance-de-these-de-giovanni-olivetti-cea-irig-spintec/
LOCATION:CNRS – Bâtiment A\, CNRS - Institut Néel 25 avenue des Martyrs\, Grenoble\, 38054\, France
CATEGORIES:Soutenance,Soutenance de Thèse
ORGANIZER;CN="IRIG - CEA":MAILTO:odile.rossignol@cea.fr
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260615T110000
DTEND;TZID=Europe/Paris:20260615T120000
DTSTAMP:20260618T011435
CREATED:20260611T102519Z
LAST-MODIFIED:20260611T102519Z
UID:10000193-1781521200-1781524800@sfp-alpes.fr
SUMMARY:Luis Alberto RAZO LOPEZ (Institut Langevin\, Paris)
DESCRIPTION:Phase retrieval based on intensity-only spatiotemporal wavefront shaping\nRésumé : \nWe introduce a phase retrieval framework based solely on intensity measurements and intensity-only spatiotemporal modulation. Our approach leverages spatiotemporal wavefront shaping to encode phase information into temporally multiplexed intensity signals\, which are subsequently decomposed in the Fourier domain. We show that the resulting temporal harmonics correspond to spiral-phase–modulated speckle components\, enabling the retrieval of phase information without direct phase-sensitive detection. We derive the harmonic structure induced by a rotating angular aperture mask and demonstrate that each harmonic carries a distinct spiral phase and amplitude weighting governed by a sinc envelope. Based on this structure\, we develop an optimization-based reconstruction algorithm that retrieves both the unknown diffuser phase and system scaling without prior knowledge of the optical transfer function. Experimental results confirm accurate reconstruction of diffuser surfaces and aberration correction\, including refocusing through digital micromirror device (DMD)-induced distortions. \nContact : dorian.bouchet@univ-grenoble-alpes.fr
URL:https://sfp-alpes.fr/event/luis-alberto-razo-lopez-institut-langevin-paris/
LOCATION:LiPhy – Salle de conférence\, LiPhy 140 avenue de la Physique\, St Martin d'Hères\, 38402\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260616T140000
DTEND;TZID=Europe/Paris:20260616T150000
DTSTAMP:20260618T011435
CREATED:20260611T103209Z
LAST-MODIFIED:20260611T103209Z
UID:10000194-1781618400-1781622000@sfp-alpes.fr
SUMMARY:Roger TORMO-QUERALT (Institute of Photonic Sciences (ICFO)\, Barcelona\, Spain)
DESCRIPTION:Carbon Nanotube Electromechanical Oscillators: where photons\, phonons and electrons meet\nRésumé : \nAchieving strong mechanical nonlinearities\, minimally invasive detection\, and control at the few-phonon level is a central challenge in the development of mechanical oscillators for quantum technologies\, including quantum information processing (1\,2)\, precision sensing (3)\, and tests of quantum mechanics (4\,5). In our group\, we aim to realize these capabilities using suspended carbon-nanotube mechanical oscillators coupled to electronic quantum dots. In this talk\, I will present results obtained with a device operating in the exotic dispersive ultrastrong-coupling regime (6\,7)\, where the interaction strength between a nanotube mechanical oscillator and a double-quantum-dot electronic two-level system (DQD-ETLS) exceeds the bare energy of the oscillator. In this regime\, we demonstrate a mechanical Kerr oscillator with an anharmonicity exceeding the state of the art for mechanical systems by four orders of magnitude (8). We read out the mechanical states using a superconducting cavity coupled to the square displacement (x²) of the oscillator (8)\, paving the way towards future quantum non-demolition (QND) cavity-based readout of mechanical Fock states (9). I will also show that the decay and decoherence rates of our ETLS charge qubit outperforms the current state of the art for 2DEG-based systems\, reaching the highest coherence values ever measured in a charge-based DQD-ETLS (10). \n1 A. D. O’Connell\, et al. Nature 464 (2010)\n2 Y. Yang\, et al. A mechanical qubit\, 386 (6723) (2024)\n3 F. Pistolesi\, et al. Phys. Rev. X\, 11\, 031027 (2021)\n4 M.F. Gely et al.\, AVS Quantum Sci. 3\, 035601 (2021)\n5 Oriol Romero-Isart. et\, al. Physical Review A\, 84 (2011)\n6 C. Samanta et al\, Nat. Phys. 19 (2023)\n7 P. Forn-Díaz et al.\, Rev. Mod. Phys (2019)\n8 C.B. Moller*\, R.Tormo-Queralt* (under review) 9 P. Arrangoiz-Ariola\, Nature volume 571 (2019)\n10 P. Scarlino Phys. Rev. Lett. 122\, 206802 (2019) \n_ \nContact : equipe-seminaires-nano@listes.grenoble.cnrs.fr
URL:https://sfp-alpes.fr/event/roger-tormo-queralt-institute-of-photonic-sciences-icfo-barcelona-spain/
LOCATION:CNRS – Salle Rémy Lemaire (K223)\, CNRS - Institut Néel 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260617T110000
DTEND;TZID=Europe/Paris:20260617T120000
DTSTAMP:20260618T011435
CREATED:20260611T105930Z
LAST-MODIFIED:20260612T140333Z
UID:10000195-1781694000-1781697600@sfp-alpes.fr
SUMMARY:Mohamed AMDDAH (LPMMC)
DESCRIPTION:Dissipative Dynamics of Phase Slips in SNS Junctions\n_ \nContact : pierre.nataf@lpmmc.cnrs.fr
URL:https://sfp-alpes.fr/event/mohamed-amddah-lpmmc/
LOCATION:LPMMC – salle Roger Maynard (G421)\, CNRS - LPMMC 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260619T110000
DTEND;TZID=Europe/Paris:20260619T120000
DTSTAMP:20260618T011435
CREATED:20260604T132608Z
LAST-MODIFIED:20260604T133618Z
UID:10000184-1781866800-1781870400@sfp-alpes.fr
SUMMARY:Jonathan HOME (ETH Zürich)
DESCRIPTION:Scaling trapped-ion quantum computers\nRésumé : \nTrapped ions are among the most promising paths to realizing quantum computers\, having exhibited the highest fidelity gates and long coherence times. Scaling up will require the adoption of new technologies\, and can be facilitated by new approaches. In this talk I will describe recent work from our group in both directions. Firstly I will describe the use of integrated optics to deliver light to multiple zones of an ion trap chip in scalable manner\, and give an impression of the new types of control which might be enabled by this approach 1\,2\,3. I will then introduce a new concept for scaling trapped-ion quantum computers based on microfabricated Penning traps\, introducing flexible 2-dimensional ion transport while removing the need for high-voltage radio-frequency fields and thus improving compatibility with standardized chip fabrication 4\,5. We have used this to perform sensing of both static and oscillating magnetic and electric fields near the chip surface\, and more recently demonstrated multi-qubit gates and control of multi-dimensional arrays of ions. \n1 K. Mehta et al. Nature 586\, 533–537 (2018)\n2 A. Ricci et al. Phys. Rev. Lett. 130\, 133201 (2023)\n3 C. Mordini et al. Physical Review X 15\, 011040 (2025)\n4 S. Jain et al. Physical Review X 10\, 031027 (2021)\n5 S. Jain et al. Nature 627\, 8004\, pp. 510–514 (2024) \n_ \nContact : michele.filippone@cea.fr
URL:https://sfp-alpes.fr/event/jonathan-home-eth-zurich/
LOCATION:GreenER – Amphi Bergès\, GreenER\, 21 avenue des Martyrs\, Grenoble\, 38031\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260619T140000
DTEND;TZID=Europe/Paris:20260619T160000
DTSTAMP:20260618T011435
CREATED:20260529T145132Z
LAST-MODIFIED:20260529T145509Z
UID:10000175-1781877600-1781884800@sfp-alpes.fr
SUMMARY:Soutenance de Thèse de Marco BIAGI (IRIG/Spintec)
DESCRIPTION:Exploration of orbital-to-spin conversion materials and integration in 3-terminal spin-orbit torque magnetic tunnel junctions\nRésumé : \nThe development of electrically controlled nanomagnets for spintronic applications\, particularly non-volatile magnetic memories (MRAM)\, is attracting strong interest due to the limitations of CMOS-based memories such as SRAM and eDRAM. Spin–orbit torque (SOT) MRAMs are promising candidates for addressing SRAM specifications; however\, current materials still suffer from limited efficiency and high resistivity\, leading to unmet write-current requirements. Recently\, studies have highlighted orbital phenomena as a potential route to enhance SOT efficiency\, owing to their larger magnitudes and availability in a broader set of materials. However\, orbital currents do not couple to magnetization in the absence of spin–orbit coupling\, requiring an orbital-to-spin conversion layer\, which motivates studies of conversion mechanisms and associated physics. \nIn this PhD work\, we evaluate promising orbital/HM/FM material systems for SOTMRAM applications. We present a comprehensive study of Ru/HM/FeCoB and Ta/W/ FeCoB systems\, where Ru and Ta act as orbital current sources\, while Ta\, W\, and Pt serve as orbital-to-spin conversion layers. Ru is predicted to exhibit one of the largest orbital Hall angles among transition metals while maintaining low resistivity. Ta\, a heavy metal with a large spin Hall effect\, is predicted to exhibit an orbital Hall angle approximately one order of magnitude larger than its spin counterpart. When a heavy metal is used as a conversion layer\, multiple spin-current contributions can coexist and add linearly to the total effective spin Hall conductivity\, potentially enhancing the overall SOT efficiency. \nWe characterized key parameters relevant to SOT magnetic tunnel junctions (MTJ) devices\, including saturation magnetization\, effective anisotropy field\, and resistivity\, and we quantified damping-like (ξDL) and field-like (ξFL) SOT efficiencies as a function of orbital and conversion layer thickness\, both in as-deposited and 300°C annealed samples. These metrics are benchmarked against reference HM/FeCoB systems to isolate the effect of the additional orbital layer. For Ru/Ta and Ru/W stacks\, limited enhancement ξFL of ξDL is observed relative to reference systems. In contrast\, Ru/Pt exhibits a twofold increase in ξDL compared to Pt alone. This difference is attributed to the stronger SOC in Pt\, which enables more efficient orbital-to-spin conversion. The independence of ξDL on Ru thickness further suggests an interfacial origin of the orbital contribution in Ru/Pt. However\, thermal annealing strongly degrades ξDL\, limiting its applicability for SOT-MRAM. In Ta/W systems\, we observe a strong enhancement of ξDL by a factor of 4.4 relative to Ta and 3.2 relative to W. A parallel-resistor model indicates that conventional SHE contributions cannot fully account for this increase\, pointing to an additional orbital-related mechanism. Extending the study to 400 °C annealing shows that ξDL remains largely stable\, indicating good thermal robustness while maintaining perpendicular magnetic anisotropy. \nLeveraging these advantages\, we further integrate the Ta/W system into SOT-MTJs and benchmark it against standard W-based MTJs. We investigate the pulse-length dependence of the critical switching current and provide a first demonstration of integrated orbital-to-spin conversion in SOT-MTJs. Ta/W devices exhibit switching currents comparable to W-based devices but have a lower switching current density and improved perpendicular magnetic anisotropy stability. Finally\, we present a proof-of-concept for vertical non-local switching of SOT-MTJ using orbital torques\, simplifying bottom-pinned SOT-MRAM fabrication. Overall\, these results demonstrate that orbital physics can be exploited to enhance SOT-MTJ performance\, simplify fabrication\, and provide a promising route toward scalable bottom-pinned MRAM technologies. \nPlus d’information : https://www.spintec.fr/phd-defense-exploration-of-orbital-to-spin-conversion-materials-and-integration-in-3-terminal-spin-orbit-torque-magnetic-tunnel-junctions/ \nPour suivre la soutenance ​​​en visioconférence : https://univ-grenoble-alpes-fr.zoom.us/j/98769867024?pwd=dXNnT3RMeThjYStybGVQSUN0TVdJdz09 \n_ \n\n\nP​resential access to the confere​nce room at CEA in Gre​​noble requires an entry authorization\, request to admin.spintec@cea.fr
URL:https://sfp-alpes.fr/event/soutenance-de-these-marco-biagi-irig-spintec/
LOCATION:CEA – Salle de Séminaire IRIG (1005 – 445)\, Laboratoire Irig/Spintec\, salle de séminaire 445\, bâtiment 1005\, CEA-Grenoble\, Grenoble
CATEGORIES:Soutenance,Soutenance de Thèse
ORGANIZER;CN="IRIG - CEA":MAILTO:odile.rossignol@cea.fr
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BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260622T140000
DTEND;TZID=Europe/Paris:20260622T150000
DTSTAMP:20260618T011435
CREATED:20260522T124820Z
LAST-MODIFIED:20260522T124835Z
UID:10000160-1782136800-1782140400@sfp-alpes.fr
SUMMARY:Maurizio SACCHI (CNRS - Institut des NanoSciences de Paris and Synchrotron SOLEIL)
DESCRIPTION:X-rays with Orbital Angular Momentum for spectroscopy and imaging\nRésumé : \nIn addition to the spin angular momentum (SAM) associated to the light polarization\, Laguerre-Gaussian light beams carry also an orbital angular momentum (OAM) of ℓ /photon [1]ℏ associated to an azimuthal dependence exp(iℓϕ) of the electric field phase. Over the last thirty years\, OAM beams at vis-IR wavelengths found applications in fields as different as biology\, telecommunication and imaging [2]. The azimuthal phase dependence\, with a singularity on the propagation axis\, is accompanied by a radial modulation of the intensity (ring-shaped beams)\, properties that have been used to modify local magnetic ordering\, to improve the spatial resolution in microscopy\, and to enhance the edge sharpness in phase-contrast imaging. \nOver the last decade\, several approaches to the generation of OAM beams at shorter wavelengths\, from XUV to hard x-rays\, were proposed. Potential applications are often based on the extrapolation of previous work carried out in the vis-IR range. For instance\, as for the SAM\, the handedness imposed by the OAM has been exploited to study magnetic materials [3] and chiral molecules [4]. The interest of extending the use of OAM beams from the vis-IR to the x-ray range has been growing steadily over the last few years. Nonetheless\, the offer of user accessible beamlines and endstations remains limited\, especially when one aims at independently varying both SAM and OAM in a controlled way. At the SEXTANTS beamline of the SOLEIL synchrotron\, we have implemented and commissioned a new setup for soft x-ray spectroscopy (absorption and resonant scattering experiments) with OAM beams [5]. \n1. L. Allen at al.\, Orbital angular momentum of light and the transformation of Laguerre-Gaussian laser modes\, Phys. Rev. A 45\, 8185 (1992).\n2. Y. Shen et al.\, Optical vortices 30 years on: OAM manipulation from topological charge to multiple singularities\, Light: Science & Applications 8\, 90 (2019).\n3. M. Fanciulli et al.\, Electromagnetic theory of Helicoidal Dichroism in reflection from magnetic structures\, Phys. Rev. A 103\, 013501 (2021); Observation of magnetic helicoidal dichroism with extreme ultraviolet light vortices\, Phys. Rev. Lett. 128\, 077401 (2022); Magnetic vortex dynamics probed by time-resolved magnetic helicoidal\ndichroism\, Phys. Rev.Lett. (2025).\n4. J. R. Rouxel et al.\, Hard X-ray helical dichroism of disordered molecular media\, Nature Phot. 16\, 570 (2022).\n5. P. Carrara et al.\, Soft x-rays with Orbital Angular Momentum for resonant scattering experiments at the SOLEIL synchrotron\, J. Synchr. Rad. 33\, 858 (2026). \nContact : matteo.dastuto@neel.cnrs.fr
URL:https://sfp-alpes.fr/event/maurizio-sacchi-cnrs-institut-des-nanosciences-de-paris-and-synchrotron-soleil/
LOCATION:CNRS – Salle Louis Weil (E424)\, CNRS - Institut Néel 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
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BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260623T110000
DTEND;TZID=Europe/Paris:20260623T120000
DTSTAMP:20260618T011435
CREATED:20260326T142350Z
LAST-MODIFIED:20260326T142357Z
UID:10000111-1782212400-1782216000@sfp-alpes.fr
SUMMARY:Lucas GOEHRING (Nottingham Trent University (UK))
DESCRIPTION:Structure formation in paints and coatings\nRésumé : \nPaints and coatings are typically a mix of small particles\, like pigments\, along with a polymer glue or binder. Similar products include inks\, varnishes\, cosmetics\, ceramics and even the lithium-ion battery electrodes that power modern electric vehicles. These materials are prepared as a liquid\, spread over a surface\, and dried.  As anyone who has painted a wall will know\, however\, this process can easily go wrong. Even a well-prepared paint can develop an undesirable skin and wrinkle\, crack\, or peel\, and these coatings can also visibly degrade over time. \nIn this talk I will go through the key stages of film formation\, or how a colloidal dispersion dries.  I will show how small angle scattering experiments (SANS/SAXS) helped to elucidate how the structure of the film changes during drying\, evolving from a dilute gas of particles\, into a transient gel where capillary pressures balance electrostatic repulsion\, to a final aggregated solid. I will then turn to look at how the insight gained has led to a better understanding of mechanical instabilities like fracture\, shear banding\, birefringence\, and peeling\, as well as revealing an unexpected route to colloidal crystallisation. \nFinally\, I will summarise our recent work using neutron scattering techniques to investigate blanching\, a degradation process that can cause a visible whitening in the traditional varnishes that are used as a protective outer coating on many historically and artistically important paintings. \nSpeaker’s website: https://www.ntu.ac.uk/staff-profiles/science-technology/lucas-goehring \n— \nOrsolya Czakkel (College 9 Secretary) \nExternal visitors may ask for a site access to tellier@ill.fr \nZoom link: https://ill.zoom.us/j/95581858117?pwd=hh9paEQj6BF8u9WYzfZkvZaGspe1i3.1  – Passcode: 078610 \n 
URL:https://sfp-alpes.fr/event/lucas-goehring-nottingham-trent-university-uk/
LOCATION:ILL – Salle de Séminaire (110-111)\, ILL 50 71 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260623T140000
DTEND;TZID=Europe/Paris:20260623T160000
DTSTAMP:20260618T011435
CREATED:20260604T144948Z
LAST-MODIFIED:20260604T144948Z
UID:10000190-1782223200-1782230400@sfp-alpes.fr
SUMMARY:Soutenance HDR de Damien CALISTE (CEA-Irig/MEM)
DESCRIPTION:Étude de mécanismes à l’échelle atomique pour les matériaux fonctionnels\, apports de la DFT comme un outils en évolution\nRésumé : \nThe purpose to use numerical tools is to treat problems where the analytical solutions are too complex or unknown. In the field of solid-state physics\, the advent of the Density Functional Theory (DFT) had a major impact on the studies of materials at the atomic scale. Its numerous implementations and ability to efficiently run on large computing infrastructures\, made it popular and it quickly became indispensable in both academic and industrial research\, enabling unprecedented insights into the electronic\, structural\, and chemical properties of complex systems. However\, the power of DFT is not solely derived from its theoretical foundations; it is equally dependent on the robustness\, efficiency\, and adaptability of the computational tools that implement it. ​ \nThis defense will deal with these two aspects: material science through DFT simulations\, and maintainance and development of large numerical infrastructures like a DFT code. ​ \nI will first address how atomistic-level simulations can be used to complement experimental characterisations\, through the example of the indirect role played by Se atoms in the efficiency improvement of CdTe solar panels. Revealing such mechanisms is important for material design\, driving material engineering by knowledge. ​ \nA second part will be dedicated to a broad overview on the physics description of a graphite electrode in a Li-ion battery. Starting from a fully charged anode\, and following the deintercalation process\, I will question what insights we can get from DFT calculations with the existing knowledge obtained from long-passed experiments as from more recent in-operando characterisation results. ​ \n​Studying the dilute regime in graphite intercalation will lead to open questions about the capability of numerical simulations to address cases where the strong interactions between the cations and the host material\, compete with the binding of the layers. To properly address such questions\, it is important to have available within DFT\, a level of theory capable of treating inhomogeneous systems made of places where covalent bonds are dominant while in other areas van der Waals interactions take the lead. These situations can be commonly found in several classes of materials\, from van der Waals heterostructures to hybrid perovskites when out-of-equilibrium processes take place\, with defect / impurity diffusion or phase / structural transitions. The recent developments of versatile meta-GGAs associated to dispersion corrections\, look promising and have demonstrated their ability to reproduce perfect van der Waals systems. Concurrently\, their usage are restricted to some codes\, hindered by the complexity in DFT implementations\, isolating the diffusion of new ideas. I believe that the advent of code generation through AI is a timely opportunity to help spreading state-of-the-art DFT developments. Such thoughts will be discussed in the last part of the defense.​ \n_ \nContact : alain.farchi@cea.fr
URL:https://sfp-alpes.fr/event/soutenance-hdr-de-damien-caliste-cea-irig-mem/
LOCATION:CEA\, entrée principale – Salle de soutenance (bâtiment A2)\, 17\, avenue des Martyrs\, Grenoble\, 38000\, France
CATEGORIES:Soutenance,Soutenance HDR
ORGANIZER;CN="IRIG - CEA":MAILTO:odile.rossignol@cea.fr
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BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260625T140000
DTEND;TZID=Europe/Paris:20260625T150000
DTSTAMP:20260618T011435
CREATED:20260529T142941Z
LAST-MODIFIED:20260529T143015Z
UID:10000172-1782396000-1782399600@sfp-alpes.fr
SUMMARY:Benjamin BACQ-LABREUIL (IPCMS\, Université Strasbourg)
DESCRIPTION:The Role of the Apical Oxygen in Cuprate High-Temperature Superconductors\nRésumé : \nScanning tunneling microscopy measurements exploiting the natural superstructure modulation of the cuprate superconductor Bi$_2$Sr$_2$CaCu$_2$O$_{8+x}$ (Bi-2212) have revealed a possible correlation between the Cu-apical-O distance and the superconducting order parameter\, as reported recently by O’Mahony et al. [1]. These observations were interpreted as evidence for a direct link between superconductivity and the charge-transfer gap\, and more broadly revived the long-standing question of the role of apical oxygens in cuprate superconductivity. In this talk\, I will discuss the impact of apical oxygen displacement on the superconducting properties of Bi$_2$Sr$_2$CuO$_{6+x}$\, Bi-2212\, and HgBa$_2$CuO$_{4+x}$ [2]\, leveraging a recently developed first-principles framework for high-temperature superconductors [3]. The quantitative agreement between our calculations and experiments allows us to unambiguously attribute the observed variations of superconducting order parameter to changes in the apical distance. We demonstrate\, however\, that the latter controls the former predominantly via the effective hole-doping of the CuO$_2$ planes\, with negligible effect on the charge-transfer gap. The modest magnitude of the order parameter modulation induced by apical-oxygen displacement alone therefore warrants caution in interpreting correlations between $T_c$ and the apical distance inferred from comparisons across different cuprate compounds. \n[1] O’Mahony\, et al.\, Proc. Natl. Acad. Sci. 119\, e2207449119 (2022) \n[2] S. Vadnais\, et al.\, arXiv:2601.16017 (2026) \n[3] B. Bacq-Labreuil\, et al.\, Phys. Rev. X 15\, 021071 (2025) \n_ \nContact : florence.levy-bertrand@neel.cnrs.fr 
URL:https://sfp-alpes.fr/event/benjamin-bacq_labreuil-ipcms-universite-strasbourg/
LOCATION:CNRS – Salle Rémy Lemaire (K223)\, CNRS - Institut Néel 25 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
END:VEVENT
BEGIN:VEVENT
DTSTART;TZID=Europe/Paris:20260625T140000
DTEND;TZID=Europe/Paris:20260625T150000
DTSTAMP:20260618T011435
CREATED:20260521T145948Z
LAST-MODIFIED:20260521T145948Z
UID:10000158-1782396000-1782399600@sfp-alpes.fr
SUMMARY:Ismaele Vincent MASIELLO (TU WIEN\, Austria)
DESCRIPTION:Nonclassicality\, quasiprobabilities and weak values explored in neutron interferometry\nRésumé : \nThe violation of Bell inequalities has demonstrated that quantum mechanics exhibits features with no classical counterpart; however\, identifying the boundary between quantumness and classicality remains a nontrivial task. Quasiprobability representations and weak values are valuable tools for investigating these boundaries\, and their physical relevance has been confirmed across a range of impactful experiments. Several of these experiments have been implemented in neutron interferometry\, a platform that has historically played a central role in the study of foundational quantum mechanics and nonclassicality. Compared to typical photonic implementations\, it is less susceptible to classical reinterpretations\, as it involves a single massive particle in a superposition of two or three spatially separated paths. Moreover\, it offers several experimental advantages\, such as macroscopic beam separation\, individual control of the sub-beams\, and long interaction and coherence times at room temperature and ambient pressure. In this talk\, I will introduce weak values and quasiprobabilities as tools to investigate the quantum–classical boundary and present results obtained in neutron interferometry.\n_ \nHanno Filter (College 3 Secretary) \nExternal visitors may ask for a site access to tellier(at)ill.fr \nZoom link : https://ill.zoom.us/j/98964195699?pwd=vPhNT17CAeoDUr7QX4PjfyPnWsHuMU.1 – Password : SeminarC3 \n  \n 
URL:https://sfp-alpes.fr/event/ismaele-vincent-masiello-tu-wien-austria/
LOCATION:ILL – Salle de Séminaire (110-111)\, ILL 50 71 avenue des Martyrs\, Grenoble\, 38042\, France
CATEGORIES:Séminaire
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