Archives des Stages et emplois - Laboratoire de Physique et Chimie des Nano-objets

Offre de thèse – Photovoltaïque à haute performance par l’assemblage de microstructures épaisses à base de nanoparticules

Giuseppe Boniello — Wed, 08 Apr 2026 11:18:22 +0000

L’article Offre de thèse – Photovoltaïque à haute performance par l’assemblage de microstructures épaisses à base de nanoparticules est apparu en premier sur Laboratoire de Physique et Chimie des Nano-objets.

Offre de stage M2 – Détection de micropolluants dans l’eau : Fabrication d’un capteur microfluidique à base d’un réseau de nanoparticules enviro-intelligentes

Giuseppe Boniello — Wed, 08 Oct 2025 13:56:26 +0000

Sujet M2 capteur microflu 2025 Nanotech-LPCNO Télécharger

L’article Offre de stage M2 – Détection de micropolluants dans l’eau : Fabrication d’un capteur microfluidique à base d’un réseau de nanoparticules enviro-intelligentes est apparu en premier sur Laboratoire de Physique et Chimie des Nano-objets.

phD thesis 2025 – 2028Fe-based nanorods for the fabrication of « green » magnets

Lucie Marpinard — Mon, 31 Mar 2025 09:56:16 +0000

phD thesis 2025 – 2028
Fe-based nanorods for the fabrication of « green »magnets

Supervisors :

Lise-Marie Lacroix, LPCNO lmlacroi@insa-toulouse.fr
Guillaume Viau, LPCNO gviau@insa-toulouse.fr
Fabienne Testard, CEA LIONS testard@cea.fr

Magnetic materials play a major role in the currentenergy and societal transitions. However,the development of sustainable yet performant materials, without critical elements such asrare-earths (RE), remains a challenge [1,2]. This thesis is part of a large project involving 5laboratories with complementary expertise in chemistry, physics, chemical engineering,artificial intelligence and data science, to develop iron-based nanorods (NRs) with optimizedmagnetic properties. Thereal scientific challengeconsists in breaking thesymmetry of the Fecrystalline structure whilekeeping an optimized aspectratio. Such control will allowachieving magnet-likeproperties in assemblies.The LPCNO has a strong expertise on the developmentof rare-earth-free

Figure 1. a) Schematic view of the « bottom-up » approach. b)Transmission electron microscopy image of Co NRs synthesized byseed-mediated growth.

The LPCNO has a strong expertise on the developmentof rare-earth-free magnets using adirected assembly approach of elementary building blocks (Fig 1a). To date, this work has beencarried out on Co nanorods (NRs), synthesized by seeded growth (Fig 1b), and has led to high-performance integrated magnets [3,4]. The CEA-LIONSis known, among others, forsucceeding in breaking the symmetry of Au, leadingto the synthesis and characterization ofAu nanorods using the seeded growth method [5,6]. At the crossroad between these twolaboratories, the aim of this PhD will be to transpose the seeded growth method on Fe NRs.An exploration of the range of parameters (nature of seeds, growth conditions, ligandconcentration) will be undertaken using conventional synthesis and microfluidic chips. Theparticles at the different stage of the reaction will be characterized by X-ray scattering (SAXS,WAXS), electron microscopy (TEM and SEM), diffraction (XRD) and magnetometry (VSM).Eventually, in-situ SAXS and WAXS experiments willbe performed combining the microfluidicchip, synchrotron radiation and AI models to determine the optimized synthesis parameters.The work will be mainly conducting at LPCNO, Toulouse with short stay visit at CEA-Lions inorder to perform SAXS/WAXS experiments. The candidate will work in close collaboration withthe two other PhD students involved in the projectand working on the AI models and on thefabrication of the microfluidic chip.

[1] Silveyra, J. M. et al. Soft Magnetic Materials for a Sustainable and Electrified World.Science 2018,362, eaao0195. [2]Gutfleisch, O.et al. Magnetic Materials and Devicesfor the 21st Century: Stronger, Lighter, and More Energy Efficient.Adv. Mater.2011,23, 821. [3] Ramamoorthy, R. K. et al. One-Pot Seed-Mediated Growth of Co Nanoparticles by the Polyol Process: Unravelingthe Heterogeneous Nucleation.Nano Lett.2019,19, 9160. [4] Moritz, P.et al.. « Procédé de Fabrication d’un Aimant Permanent Ou Doux ». PCT/FR2019/053046. [5] Hubert, F. et al. Growth andovergrowth of concentrated gold nanorods: time resolved SAXS and XANES. Crystal growth & design 2012, 12(3), 1548. [6]Canbek Ozdil, Z. C. et al Competitive Seeded Growth: An Original Toolto Investigate Anisotropic Gold Nanoparticle GrowthMechanism. J. Phys. Chem. C 2019, 123(41), 25320.

L’article phD thesis 2025 – 2028Fe-based nanorods for the fabrication of « green » magnets est apparu en premier sur Laboratoire de Physique et Chimie des Nano-objets.

PhD thesis starting in October 2025 Fe-based nanorods for the fabrication of rare-earth free magnets

Lucie Marpinard — Mon, 31 Mar 2025 09:23:52 +0000

PhD thesis starting in October 2025
Fe-based nanorods for the fabrication of rare-earth free magnets

Supervisors :

· Lise-Marie Lacroix, LPCNO.lmlacroi@insa-toulouse.fr

· Guillaume Viau, LPCNO.gviau@insa-toulouse.fr

· Julian Carrey, LPCNO.julian.carrey@insa-toulouse.fr

Magnetic materials play a major role in the currentenergy transition. However, thedevelopment of sustainable yet performant permanentmagnets, without critical elementssuch as rare-earths (RE), remains a challenge [1].A promising alternative to Nd-based magnetsconsists of a nanostructured material made of Fe16N2nanorods exhibiting controlleddimensions (diameter < 20 nm; length > 100 nm). This gathers two scientific challenges : first,the Fe16N2phase is metastable and thus hard to stabilize; second, the chemical synthesis ofanisotropic Fe-based objects has never been reported yet.In the framework of a large project gathering 5 laboratories with complementary expertise, anew approach consisting in the oriented attachmentof preformed Fe nanoparticles (NPs) andtheir controlled nitridation is proposed using a high-frequency alternating magnetic field asdriving force (Figure 1). We will take advantage ofi) the chain alignment of the NPs undermagnetic field and ii) the induced heating to promote their coalescence [2]

Figure 1. a) TEM image of the Fe(0) nanoparticles.b) Schematic view of the strategy proposed for theorientedattachment of Fe(0) NPs and their nitridation undera high-frequency alternating magnetic field

The LPCNO has a strong expertise in the synthesis of metallic Fe-based NPs using anorganometallic approach [3,4] and has been workingfor almost 10 years on the developmentof rare-earth-free magnets using a directed assembly approach of NPs [5]. The aim of this PhDwork will be to characterize the heat power of NPsas a function of their shape and chemicalstate, design and fabricate a reactor to allow foran in-situ characterization using X-Rayscattering (SAXS and WAXS) and X-Ray absorption (XAS), analyze the large data set obtainedwith machine learning tools which are currently being developped at LPCNO. Understandingthe mechanism will allow optimizing the reaction condition to eventually yield Fe16N2nanorods.
For such a pluridisciplinary thesis, we are lookingfor a candidate with a physics/engineeringbackground and experience on characterization techniques (XRD, TEM, SAXS). Programmingand/or chemical synthesis will be a plus. The person is expected to demonstrate curiosity andscientific rigor as well as good communication andwriting skills.

[1] Gutfleisch, O.et al. Magnetic Materials and Devices for the 21st Century: Stronger, Lighter, and More Energy Efficient.Adv.Mater.2011,23, 821. [2]J. M. Asensio et al. To Heat or not to Heat: a study of the performances of Iron Carbide Nanoparticlesin Hyperthermia,Nanoscale,2019,11, 5402 ; [3] Lacroix, L.-M. et al. Iron NanoparticlesGrowth in Organic Super-Structures,J.Am. Chem. Soc.,2009,131, 549 [4] Garnero, C. et al. Chemical Ordering in Bimetallic FeCo Nanoparticles : from a direct chemicalsynthesis to application as efficient high frequency magnetic material,Nanoletters201919, 1379 [5] Moritz, P.et alMagnetophoresis-Assisted Capillary Assembly: a Versatile Approach for Fabricating Tailored 3D MagneticSupercrystals,ACS Nano2021,15, 5096

L’article PhD thesis starting in October 2025 Fe-based nanorods for the fabrication of rare-earth free magnets est apparu en premier sur Laboratoire de Physique et Chimie des Nano-objets.

Poste d’ingénieur de recherche (H/F): Synthèse en flux de nanobâtonnets de cobalt pour des aimants permanents sans terre rare

Lucie Marpinard — Wed, 14 Feb 2024 07:57:33 +0000

Poste d’ingénieur de recherche (H/F): Synthèse en flux de nanobâtonnets de cobalt pour des aimants permanents sans terre rare

Contrat : 15 mois

Rémunération : entre 2.782,84 à 3142,07 € brut mensuel selon expérience

Date d’embauche prévue : 1er Avril

Contact : Lise-Marie Lacroix – lmlacroi@insa-toulouse.fr; Isaac Rodriguez-Ruiz – isaac.rodriguez-ruiz@cnrs.fr

Lien vers le portail d’emploi CNRS : https://emploi.cnrs.fr/Offres/CDD/UMR5215-LISLAC-001/Default.aspx

L’article Poste d’ingénieur de recherche (H/F): Synthèse en flux de nanobâtonnets de cobalt pour des aimants permanents sans terre rare est apparu en premier sur Laboratoire de Physique et Chimie des Nano-objets.

Thèse : Nanoparticle based catalysis

Lucie Marpinard — Mon, 15 Jan 2024 14:55:23 +0000

Thèse : Nanoparticle based catalysis

Experimental thesis in the Nanostructure and Organometallic Group, codirection : Lise-Marie Lacroix (LPCNO) and Pr. Richard Tilley (University of New South Walles, Signey, Australia). Duration : 3 to 4 years.

Location : LPCNO, INSA, Toulouse (France) and UNSW, Sidney (Australia)

Key words : Metallic nanoparticle, single atom, electrochemistry

description and candidacy : https://aufrande.eu/position/dc21/

L’article Thèse : Nanoparticle based catalysis est apparu en premier sur Laboratoire de Physique et Chimie des Nano-objets.

Postdoc Offer: Topological insulators as spin-orbit torque source materials

Francis Chouzenoux — Mon, 22 May 2023 08:11:38 +0000

Research location: Laboratory: LPCNO-INSA Toulouse, 135 avenue de Rangueil 31077 Toulouse
Themes: Topological insulators as spin-orbit torque source materials Start date: 2 October. Duration: 18 months
Contract: Supervisors: Thomas Blon (LPCNO) – Sébastien Plissard (LAAS)
thomas.blon@insa-toulouse.fr

Spin-orbit torque, which results from the charge-spin conversion in material with a large
spin-orbit, is an effective method for the electrical control of the magnetization of an adjacent
magnetic layer. One of the best charge-spin converters are expected to be topological
insulators because of their spin polarized surface states. In the framework of a collaboration
between the LPCNO and the LAAS laboratories, we investigate topological insulators as spin-
orbit torque source materials for the electrical control of perpendicularly magnetized thin films.
The LAAS partner has recently demonstrated the MBE growth of high quality BiSb(0001)
topological insulator thin films on GaAs(111) substrates [1], and the existence of topological
states using Hall measurements [2]. Spin-polarized surface surfaces states in topological
insulators are able to generate spin-orbit torque on an adjacent magnetization similarly to the
spin Hall effect and Rashba-Edelstein effect [3]. For this purpose, we demonstrated in LPCNO
the sputtering growth of ultrahin magnetic thin films with perpendicular magnetic anisotropy on
BiSb(0001).

The main objective of the 18-months post-doc will be to perform the magnetotransport
measurements on Hall cross-designed samples of topological insulator/ferromagnet
heterostructures to demonstrate efficient magnetization manipulation thanks to charge current
injection in BiSb. The work plan concerns (i) the sputtering growth of ultrathin magnetic films
on BiSb fabricated by the LAAS partner, (ii) the design of samples into Hall bars thanks to
optical and electronic lithography, and (iii) the magnetotransport measurement of the
topological insulator / ferromagnet heterostructures at low and room temperatures. This works
will be then extended to the topological insulator BiSbTeSe which presents the advantage of
a larger bulk band gap than BiSb that would reduce bulk intrinsic conduction.
This work will be conducted within the frame of a LabeX NanoX research program
(LPCNO/CEMES/LAAS). The post-doc will interact with the different academic partners of the
project, participate in the design and the characterization of the heterostructures and
communicate on the results.

Methods & Techniques
– Magnetism of thin films (required)
– Experience in magnetotransport measurement (desired)
– Experience in optical and electronic lithography (desired)
– Thin film growth, sputtering (optional)
– Programming skills in Labview, LabwindowsCVI, Matlab, etc (optional)
– Excellent organizational and scientific writing skills in English (required)
– Good communication skills (desired)

[1] D. Sadek, D.S. Dhungana, R. Coratger, C. Durand, A. Proietti, Q. Gravelier, B. Reig, E. Daran, P-F.
Fazzini, F. Cristiano, A. Arnoult, S.R. Plissard, ACS Appl. Mater. Interfaces 13 36492 (2021)
[2] D. Sadek, R. Daubriac, C. Durand, R. Monflier, Q. Gravelier, A. Proietti, F.Cristiano, A. Arnoult,
S.R. Plissard, Cryst. Growth Des. 22 5081 (2022)
[3] Q. Shao, et al., IEEE Trans. Mag. 57 800439 (2021)

L’article Postdoc Offer: Topological insulators as spin-orbit torque source materials est apparu en premier sur Laboratoire de Physique et Chimie des Nano-objets.

Propriétés optiques et de spin de nouvelles hétérostructures de van der Waals

Laurent Lombez — Wed, 29 Mar 2023 08:13:52 +0000

Thèse expérimentale dans le groupe Optoélectronique quantique

Durée: 3 ans

Lieu: Laboratoire LPCNO sur le campus INSA, Toulouse (France)

Mots clés: Semiconducteur, Matériaux 2D, Optoélectronique, Spintronique, Dichalcogénures, Pérovskites

Lien et détail : Site École Doctorale

Contacts :

andrea.balocchi@insa-toulouse.fr; marie@insa-toulouse.fr

L’article Propriétés optiques et de spin de nouvelles hétérostructures de van der Waals est apparu en premier sur Laboratoire de Physique et Chimie des Nano-objets.

Archives des Stages et emplois - Laboratoire de Physique et Chimie des Nano-objets

Offre de thèse – Photovoltaïque à haute performance par l’assemblage de microstructures épaisses à base de nanoparticules

Offre de stage M2 – Détection de micropolluants dans l’eau : Fabrication d’un capteur microfluidique à base d’un réseau de nanoparticules enviro-intelligentes

phD thesis 2025 – 2028Fe-based nanorods for the fabrication of « green » magnets

phD thesis 2025 – 2028Fe-based nanorods for the fabrication of « green »magnets

PhD thesis starting in October 2025 Fe-based nanorods for the fabrication of rare-earth free magnets

PhD thesis starting in October 2025Fe-based nanorods for the fabrication of rare-earth free magnets

Poste d’ingénieur de recherche (H/F): Synthèse en flux de nanobâtonnets de cobalt pour des aimants permanents sans terre rare

Thèse : Nanoparticle based catalysis

Thèse : Nanoparticle based catalysis

Postdoc Offer: Topological insulators as spin-orbit torque source materials

Propriétés optiques et de spin de nouvelles hétérostructures de van der Waals

phD thesis 2025 – 2028
Fe-based nanorods for the fabrication of « green »magnets

PhD thesis starting in October 2025
Fe-based nanorods for the fabrication of rare-earth free magnets