All opportunities

HyperAI: Edge-AI Solutions for Real-Time Hyperfrequency Material    Characterization 

Context:
The electrical characterization of materials at hyperfrequencies is essential for understanding their intrinsic electronic
structure and charge carrier dynamics. Permittivity and dielectric losses are a major concern in this field, as they directly impact signal
integrity and propagation within high-speed electronic systems. Due to the stringent requirements of advanced System-on-Chip (SoC)
and System-in-Package (SiP) technologies, in situ measurements are necessary, as manufacturing processes (ie solvent deposition,
drying, and polishing) can significantly alter the electrical properties of materials, thereby affecting the overall performance of
interconnects operating at frequencies from 8 to 20 GHz. Conventional methods typically involve two stages: first, measuring the S
parameters of the structures using a Vector Network Analyzer (VNA), followed by solving the inverse problem through back-simulation
(Houzet, 2021). The latter step is computationally intensive, often relying on simulation through finite element methods (such as Ansys
HFSS) to address our specific challenges. Conducting such instrumentation remains a significant scientific challenge, particularly due
to the high computational effort required and the lack of automation in such a method.

Integrating AI-driven instrumentation could streamline the process, reducing computational load and enhancing the efficiency
of inverse problem-solving. A new hardware design is emerging from neural networks implementation with electronic circuits, often
named edge AI. Artificial Neural Networks (ANNs) are computational models designed for real-time computing for applications such
as classification of material samples through their data characteristics. Spiking Neural Networks (SNNs), also referred to as the third
generation of ANNs, are emergent devices who effectively bridge the gap between ANNs and natural intelligence in low-power devices
(Shrestha, 2022). This enables the implementation of AI solutions in-situ, ie as close as possible to the material under test. The
implementation of SNNs is performed on neuromorphic processors such as Truenorth (DeBole, 2019), SpiNNaker (Furber, 2014), and
Loihi (Orchard, 2021). These solutions fully exploit the sparsity of events and offer remarkable efficiency. However, neuromorphic
chips cannot still be considered mainstream in the market, due to costs and availability. A low-cost, low-power solution is found on
hardware-friendly neural networks in micro-controllers such as TinyOL (Ren, 2021), TinyTL (Cai, 2020), and MCUNet (Lin, 2020).

Objective:
The main goal of HyperAI is to accurately characterize the complex permittivity of materials using edge-AI solutions for
real-time computing. This is approached through a two-stage methodology:

• a. Extraction method using transmission lines (e.g., CPW, CPWG, CPS) is employed on materials with known properties to build
  a database of measurement data. By varying transmission line types on the same material, we can create a robust dataset suitable
  for training a neural network, enabling automated and efficient material characterization.
• b. Transform an AI model into a hardware-friendly model. Flexibility, surface area, latency, memory consumption, energyefficiency, and reliability are addressed by this study. An STM32 (B-U585I-IOT02A) and an FPGA (ICE40UP5K-B-EVN)implementation should be investigated.

Keywords:
microwave instrumentation, convolutional neural networks, edge-AI, IoT.

Project Supervision:
CROMA laboratory is represented by Pietro M. FERREIRA, Full Professor at Université de Savoie Mont Blanc,
and Gregory HOUZET, Associate Professor at Université de Savoie Mont Blanc. Prof. FERREIRA has a research interest in microwave
instrumentation, neuromorphic circuits, and ultra-low power solutions. Prof. HOUZET has a research interest in materials science,
microwaves, and applied physics. Candidate will be to the tools and scientific methods of the research topic. Practical activities and
real-world scenarios are planned, including microwave measurements, scientific writing, communication and public speaking, result
quality, time management, and research project management.

Candidate Profile:
The candidate profile required for the project is a young professional holding a master’s degree in Eletrical or
Electronics Engineering, interested in the scientific field of embedded electronics, microwave, and AI. He/She must be motivated,
passionate about research in a multidisciplinary field and an organized person using scientific methods. He/She must justify good
academic tracks in maths and applied physics; an experience in design flow; linguistic competence in English (B2 written and spoken);
linguistic competence in French is a plus.

Intellectual Property:
Being fundamental scientific research, this subject is not attached to any industrial project. Intellectual property
will be promoted through scientific communications favoring the open science policy of the French government.

Bibliography:
10.1016/j.mejo.2021.104990, 10.1109/MCAS.2022.3166331, 10.1109/MC.2019.2903009, 10.1109/JPROC.2014.2304638,
10.1109/SiPS52927.2021.00053, 10.1109/IJCNN52387.2021.9533927, https://dl.acm.org/doi/abs/10.5555/3495724.3496671,
https://dl.acm.org/doi/abs/10.5555/3495724.3496706.

• Keywords : Engineering sciences, Electronics and microelectronics - Optoelectronics, CROMA, FMNT
• Laboratory : CROMA / FMNT
• CEA code : CROMA-DHREAMS-03-10-2025
• Contact : marisfep@univ-smb.fr

Alternative methods based on dynamic detection  for a new generation of ISFET-like biosensors in graphene

                                        Deadline for application: 18th of June 2024, beginning of contract: 1st of Oct. 2024

Place:
CROMA (Minatec) and Néel Institut, Grenoble (France)

Advisors:
Irina Ionica (Associate Professor Grenoble INP),
Cécile Delacourt (CNRS rechercher, Néel Institut),

Context and objectives:
This thesis is placed in the context of biochemical detection with ISFETs (Ion Sensing Field Effect Transistors), for which
the current which passes through the transistor channel is modulated by the presence of the charges to be detected
in its proximity. In the majority of cases, detection is done in real time by monitoring the drain-source current of the transistor channel.
Quantitative measurement could be done by calibrating the drain current as a function of the gate voltage of the transistor relative to the load to be detected. This method which has already been used for many demonstrators and
applications, uses the monitoring of a quantity quasi-static (e.g. the threshold voltage of the transistor), which non-discriminatorily encompasses all type of charge contained in the solution and sufficiently close to the channel (ions, fixed charges adsorbed on the surface of the device, interface states etc).
Unfortunately, in a “non-laboratory” application, a solution does not only contain the element we wish to detect, but many others and it would be important to identify typical electrical responses associated with the constituents. Dynamic approaches, such as non-equilibrium potential or low-frequency noise, are promising because they offer, for example, the possibility of searching for specific signatures depending on the measurement frequencies.

The objective of this project is therefore not to show another demonstrator which would improve one or several
figures of merit for a given application, but rather to explore dynamic detection alternatives with an ISFET, to
study/identify the mechanisms that are responsible for the particular electrical responses of the sensor. At
CROMA, we showed that the out of equilibrium body-potential response in device fabricated on silicon-on
insulator (SOI) 1 and due to the presence of Schottky barriers at the contacts2 can be used for sensing3.
The aim of this thesis is first to implement similar methods for graphene field effect transistors and benchmark
the dynamic detection with the quasi-static and more conventional approach. At Neel, we have demonstrated
the ability to fabricate array of GFETs that offers many suitable properties for sensing living matters4 and
biochemical compounds5. Sensors manufactured on graphene will benefit from the flexibility of the technology
in order to study a wide range of options to understand the mechanisms involved and to optimize the sensors.
Modelling and simulation components will elegantly complete the project for understanding of the phenomena
and will provide keys for the optimization of future sensors.

Work do be done:
The PhD student will develop the complete chain, from device fabrication, electrical measurements in equilibrium and dynamic conditions, sensing layer and surface functionalization for specific detection applications, modeling and simulation, allowing the comprehension of physical phenomena involved
and the optimization for the sensor. To remain more generic at first, ionic solutions close to those used in cell culture media with compositions simplified (e.g.: a single type of ion) and variable concentrations will make it possible to evaluate the mechanisms and detection improvements with dynamic methods (nonequilibrium potential and/or low frequency noise). More pragmatic applications will be explored in the second half of the thesis (e.g. neuronal sensing).

1M. Alepidis, A. Bouchard, C. Delacour, M. Bawedin and I. Ionica, “Out-of-Equilibrium Body Potential Measurement on Silicon-on-Insulator
With Deposited Metal Contacts,” in IEEE Transactions on Electron Devices, vol. 67, no. 11, pp. 4582-4586, 2020
2M. Alepidis, G. Ghibaudo, M. Bawedin & I. Ionica, Origin of the Out-of-Equilibrium Body Potential In Silicon on Insulator Devices With
Metal Contacts. IEEE Electron Device Letters, 42(12), 1834-1837, 2021
3M. Alepidis, A. Bouchard, C. Delacour, M. Bawedin, & I. Ionica, Novel pH sensor based on out-of-equilibrium body potential monitored in
silicon on insulator with metal contacts. In ECS Meeting Abstracts (No. 59, p. 1589). IOP Publishing, 2021
4Dupuit, V., Terral, O., Bres, G., Claudel, A., Fernandez, B., Briançon-Marjollet, A., & Delacour, C. (2022). A multifunctional hybrid graphene
and microfluidic platform to interface topological neuron networks. Advanced Functional Materials, 32(49), 2207001.
5Terral, O., Audic, G., Claudel, A., Magnat, J., Dupont, A., Moreau, C. J., & Delacour, C. (2024). Graphene field-effect transistors for sensing
ion-channel coupled receptors: towards biohybrid nanoelectronics for chemical detection. arXiv preprint arXiv:2402.04378.

Knowledge and skills required:
The candidate must have a solid knowledge of physics of semiconductors and devices. Clean-room fabrication, electronics of measurement systems, notion of chemical physics, surface physics or electrochemistry would be appreciated to better understand the interaction at the interface with the top gate liquids. The candidate is expected to enjoy experimental work and the development of adapted measurement protocols.
Scientific curiosity, motivation, creativity, tenacity are mandatory qualities in order to take full advantage of the scientific environment of this thesis and to gain excellent expertise for his/her future career. The topic is in the field of applied physics, but close to the fundamental physics, as well as to the industrial world. After the PhD, the candidate will easily adapt to both academic and industrial research environments.

The candidate must have a very good academic record, with high grades.
For the application, send your CV, motivation letter, track of records for your masters and recommendation letter(s).

• Keywords : Engineering science, Engineering science, Engineering sciences, Electronics and microelectronics - Optoelectronics, CROMA, FMNT
• Laboratory : CROMA / FMNT
• CEA code : CROMA-CMNE-05-31-2024
• Contact : irina.ionica@grenoble-inp.fr

Simulation, fabrication and characterization of transparent piezoelectric transducers based on ZnO nanowires

Detailed Topic
Piezoelectric devices are attracting growing interest as a micro-source of energy by harvesting mechanical ambient energy, and as sensors via the direct piezoelectric effect. In this context, semiconducting materials in the form of nanowires constitute a promising building block for the fabrication of innovative devices. The nanowires typically exhibit diameters of several tens of nanometers along with a length of around one micrometer. Thanks to that geometry, they generally present an excellent crystalline quality and benefit from remarkable physical properties that are related to their high surface/volume ratio. Zinc oxide (ZnO) as a biocompatible semiconductor composed of abundant elements specifically has numerous assets and can be grown in the form of nanowires by a large number of deposition techniques. Owing to its wurtzite crystalline structure, ZnO nanowires grow along the piezoelectric c-axis. Vertically aligned ZnO nanowire arrays are thus sensitive to mechanical constraints and are liable to be integrated into piezoelectric nanocomposites aiming either to sense mechanical inputs (e.g. fingerprint scanners) or at harvesting with a good efficiency the mechanical energy in the environment and hence playing the role of an energy micro-source.

The objective of this PhD thesis is to explore theoretically and experimentally the performance improvement of high-density arrays of ultimate-size ZnO NWs on a transparent substrate (i.e. glass) covered by a transparent conductive electrode (AZO, etc.). ZnO nanowires with controlled dimensions and properties (surface states, doping) will be developed using a low-cost, low-temperature, chemical deposition technique with a low environmental impact and a high industrial potential. The integration into devices will be performed based in the know-how of the laboratory consortium. Advanced complementary characterization techniques will be used at device and nanowire level: Home-made set-ups will be used at device level. Complementary AFM platforms (SSRM, SCM, TUNA, SMIM, etc.) will be used to characterize single nanowires. All these experimental data (geometry, doping, surface states) will help us to build and validate a simulation platform both at single nanowire and device level. The simulation platform will provide optimization guidelines for future devices sensors and energy harvesting devices.

References:
1. M. Parmar et al. Nano Energy 56 859-867 (2019). DOI: ttps://doi.org/10.1016/j.nanoen.2018.11.088
2. S. Lee et al. Adv. Funct. Mater. 24 1163-1168 (2014). DOI: https://doi-org.gaelnomade-2.grenet.fr/10.1002/adfm.201301971
3. J. Villafuerte et al, Nano Energy 114 108599 (2023), https://www.sciencedirect.com/science/article/abs/pii/S2211285523004366
4. T. Jalabert et al. Nanotechnology 34 115402 (2023). DOI 10.1088/1361-6528/acac35
5. R. Tao et al., Adv. Electron. Mater. 4(1) 1700299 (2018). DOI: 10.1002/aelm.20170029
6. A. Lopez et al, Nanomaterials 11(4) 941 (2021). https://doi.org/10.3390/nano11040941
7. A. Lopez et al., Journal of Physics D: Applied Physics 56 125301 (2023). DOI 10.1088/1361-6463/acbc86
8. C. Lausecker et al. Inorganic Chemistry 60 (3) 1612-1623 (2021) https://doi-org.sid2nomade-2.grenet.fr/10.1021/acs.inorgchem.0c03086
9. Q. C. Bui et al., ACS Appl. Mater. Interfaces 12 (26) 29583–29593 (2020) https://doi-org.sid2nomade-1.grenet.fr/10.1021/acsami.0c04112
10. M. Manrique et al., Energy Technol. 2301381 (2024), https://onlinelibrary.wiley.com/doi/10.1002/ente.202301381

Location
The candidate will work in the Micro Nano Electronics Devices (CMNE) group from the Centre for Radiofrequencies, Optic and Micro-nanoelectronics in the Alps (CROMA), in the Nanomaterials and advanced heterostructures (NanoMAT) group from the Laboratory in Materials Science and Physical Engineering (LMGP), in the PROSPECT group from LTM and the Nanocharacterization platform team (PFNC) from CEA-LETI.

Web sites: https://croma.grenoble-inp.fr/,
http://www.lmgp.grenoble-inp.fr/,
https://ltm.univ-grenoble-alpes.fr/,
https://ltm.univ-grenoble-alpes.fr/research ,
https://www.leti-cea.fr/cea-tech/leti/Pages/recherche-appliquee/infrastructures-de-recherche/plateforme-nanocaracterisation.aspx

Profile & Required Skills
The applicant should be an Engineering School or Master 2 student in the fields of electronics, nanosciences and/or semiconductor physics. It is desirable that the candidate has knowledge in one or more of these areas: semiconductor physics, finite element simulation, Atomic Force Microscopy (AFM), clean room techniques and associated characterizations (SEM, etc.). The grades and the rank as undergraduate and especially at the Master degree are a very important selection criterion for the doctoral school. Specific skills for teamwork and oral and written English expression will be appreciated. We are looking for dynamic and highly motivated candidates.

PhD Thesis Funding:
Funding is available via the Microelectronics LABEX (2024 – 2027) joining CROMA, LMGP, LTM and CEA-LETI in the Grenoble region.

Contacts

Dr. Gustavo ARDILA gustavo.ardila@univ-grenoble-alpes.fr Tel : 04.56.52.95.32
Dr. Vincent CONSONNI vincent.consonni@grenoble-inp.fr Tel : 04.56.52.93.58
Dr. Bassem SALEM bassem.salem@cea.fr Tel : 04.38.78.24.55
Dr. Gwenael LE RHUN gwenael.le-rhun@cea.fr Tel : 04.38.78.12.29

• Keywords : Engineering sciences, Electronics and microelectronics - Optoelectronics, CROMA, FMNT, Leti, LMGP, LTM
• Laboratory : CROMA / FMNT / Leti / LMGP / LTM
• CEA code : CROMA-CMNE-05-28-2024
• Contact : gustavo.ardila@univ-grenoble-alpes.fr

                                                    PhD Position 2024:

Co-Integration of Photonic Multichip Module for THz Frequency Generation

KEYWORDS :
Laser, Integrated Optics, TeraHertz, Communications

CONTEXT:
The technological development of communications devices, new and futures uses such as video conferencing, streaming, Internet of Things (IOT), 6G, AI, continue to further increase the pressure on telecommunications systems to reduce latency while simultaneously increasing both data rates and the number of connected devices. This recurring problem in the world of telecommunication leads to different communication generation (3G,4G, 5G…).
The frequency bands currently used for telecommunications already cover a large part of the spectrum, including the experimental bands at 60 GHz in the 5G standard. To tackle this problem, 6G plans to use sub-terahertz frequencies (>100GHz) and European roadmap expects to launch commercial products as soon as 2030. Systems operating at such frequencies are difficult to conceive because they are not compatible with standard architectures. Optical technics offer competitive solutions to reach these band, and even higher frequencies. Such realization is also of interest for a wide range of application, including spectroscopy, sensing, radars…
The ideal solution would rely on high performance integrated devices, compatible with current communications systems and capable of evolving to meet the demand of future needs.
At the CROMA laboratory, we recently demonstrated the use of co-integrated lasers on glass for communication system and the generation of continuous carrier at frequency up to terahertz (300GHz) with outstanding spectral properties.

OBJECTIVES:
The PhD work will be carried out as a part of a national research project, involving academic and industrial partners. Our goal is to fabricate a co-integrated multi-chip module for the generation and high speed modulation of terahertz signals. The candidate will focus on the design, manufacturing, characterization and simulation of the laser modules. The integrated laser chips will be produced using the technological facilities available at the CROMA,
including dedicated clean room, with the help of technical support, and advanced characterization systems (atomic force microscopy, dedicated optical benches…).
The laser chip will be optically and mechanically interfaced with a Lithium Niobate chip realized by an industrial partner, specifically for this project. Consequently, the applicant will be involved in the co-design of the two structures and in the definition of interconnecting solution of the two chips. The module will be packaged to be characterized and tested by different partners. The candidate will be involved in experiments at the different sites during
the project.

EXPECTED WORK:

• Model and simulation of the manufacturing process, including the fabrication of waveguides using ion exchange techniques and the realization of Bragg grating by photolithographic process.
•  Laser Manufacturing including clean room process, molecular bonding, dicing and polishing

PhD Position

•  Characterization of components, including geometrical (AFM) and optical evaluation (mode profile, gain/loss, spectral measurements… )
• Advanced characterizations: optical intensity noise, optical and RF linewidth will be estimated using opto-RF characterizations. Preliminary communication experiments will be carried-out at the CROMA laboratory using advanced modulations, including optical coherent formats.
• Collaboration with industrial and academic partners from design to experimental validation.

The work plan is composed of different steps:

• bibliographic studies to determine the current state-of-art and position the thesis results
• Analysis and handling of in-house existing simulation tools
•  trainings on fabrication process and characterization tools
• reporting : technical reports, scientific publication and conferences

APPLICANTS:
We are looking for candidates inclined to develop advanced skills in the manufacturing and characterization of integrated optics and laser devices. Theoretical training in electromagnetism and laser physic is highly recommended, if not essential. The doctorate will benefit from an environment recognized both for its scientific level (in the top 5 of the world’s innovative cities, 25.000 researchers, 65000 Students…) and for its environment (French Alps).

The laboratory facilities being located in secured areas, the final decision is also depending on the acceptance of the application by a security officer.

The thesis funding is part of a national research project already underway.
Applications should include CV, cover letter, academic marks and diplomas.
Expected starting date: Oct. 2024

For more details, please contact:
Julien POËTTE julien.poette@grenoble-inp.fr
Lionel BASTARD lionel.bastard@grenoble-inp.fr
Jean-Emmanuel BROQUIN jean-emmanuel.broquin@grenoble-inp.fr

• Keywords : Engineering sciences, Electronics and microelectronics - Optoelectronics, CROMA, FMNT
• Laboratory : CROMA / FMNT
• CEA code : CROMA-PHOTO-03-19-2024
• Contact : julien.poette@grenoble-inp.fr

Thesis topics 2024
Development and implementation of microwave characterization techniques
for molding resins used in 3D integrated circuit packaging

Contexte et objectif :
Dans le cadre d’un projet IPCEI (Projets Importants d’Intérêt Européen Commun) en  collaboration avec la société STMicroelectronics, nous nous intéressons à la caractérisation  diélectrique hautes fréquences (jusque 100 GHz) de résines de moulage. Ces dernières sont  nécessaires à la réalisation des boitiers d’encapsulation (packaging) des circuits intégrés 3D.
Le rôle des boitiers est d’assurer une isolation électrique et une protection mécanique des  circuits intégrés.

La caractérisation consiste à déterminer les propriétés électriques des résines, notamment la permittivité complexe (appelée aussi « fonction diélectrique » ou paramètres diélectriques), sur une large bande de fréquence (1 GHz – 100 GHz). Elle requiert deux étapes : une étape de mesure hyperfréquence et une étape d’extraction de la fonction diélectrique à partir des paramètres mesurés.
La connaissance des propriétés électriques des résines est essentielle pour évaluer et prédire les performances des circuits intégrés(C.I.). Le cas échéant, les performances des C.I. pourront être optimisées en choisissant les résines ayant les meilleures propriétés pour une application donnée.

Description de travaux à réaliser :
L’originalité de ce travail de thèse consiste à mettre en œuvre différentes techniques microondes ou hyperfréquence de caractérisation afin d’extraire les paramètres diélectriques des résines de moulage sur un large spectre de fréquence.
Les techniques à développer pourront dans un premier temps s’appuyer sur des méthodes classiques et connues, si les contraintes liées à leurs mises en œuvre restent limitées. Il s’agit en particulier des techniques de caractérisation suivantes :

• En lignes de transmission, en guides d’ondes. Techniques large bande de fréquence dites guidées.
• En cavités résonantes, résonateurs en ligne de transmission ou en anneau. Techniques à fréquences discrètes dites résonnantes.

L’intérêt de mettre en œuvre les différentes techniques exposées ci-avant réside dans la possibilité de réaliser des comparaisons croisées des résultats obtenus. Ceci permettra aussi de pouvoir valider des techniques récemment développées ou inédites dans leur mise en œuvre, potentiellement bien mieux adaptées à notre problématique. Ces techniques sont décrites ci-après, leurs développements figurent aussi au programme de ces travaux de thèse.
Dans une seconde étape, il sera demandé d’apporter une contribution conséquente sur :

• Le perfectionnement d’une méthode de caractérisation [1] [2] ne demandant pas de concevoir des dispositifs ou cellules de test spécifiques : le matériau (la résine de moulage) est analysé tel qu’il se présente. Il s’agit d’une méthode dite par « posé de pointes » que le laboratoire a commencé à développer et qui a fait l’objet de deux publications. Cette méthode demande néanmoins des améliorations sur les aspects suivants :
  * La précision des pertes diélectriques extraites (rappels : les pertes diélectriques sont associées à la partie imaginaire de la permittivité complexe d’un matériau).         * Le fait de pouvoir s’affranchir de la mesure d’un second matériau de référence pour pouvoir extraire la permittivité complexe des résines de moulage, le premier matériau de référence étant l’air. Des réflexions sont actuellement menées pour s’affranchir de cette mesure étant donné qu’elle conduit à faire une hypothèse forte sur le processus de caractérisation.

Le développement d’une méthode de caractérisation en espace libre. Ce travail est encore inédit pour le laboratoire, notamment au regard des fréquences visées et des contraintes engendrées par la faible maturité technologique (l’échantillon de test ne peut pas prendre toutes les formes et dimensions à souhait) des résines de moulage. L’échantillon de résine de moulage sera placé entre deux antennes [3]. L’analyse pourra s’effectuer au moyen :

•  d’une mesure différentielle en transmission de l’échantillon.
•  d’une routine d’extraction des paramètres diélectriques. Cette routine sera à développer.

Dans cette technique, les antennes étant forcément opérationnelles sur une plage de fréquences donnée, la mesure n’est plus dite large bande. Ainsi, il est envisagé d’utiliser plusieurs jeux d’antennes pour couvrir un spectre de fréquence plus large.

Une ouverture sur un travail conduisant au développement d’une technique de caractérisation qui permet l’extraction de la fonction magnétique, conjointement à celle diélectrique, est également envisagée. L’impact de la température et des procédés de fabrication microélectronique sur ces fonctions pourra également être étudié ainsi que les performances d’un composant typique (ligne de transmission par exemple) en présence de la
résine de moulage.

Pour débuter les travaux sur des bases solides et des pistes pertinentes, il s’agira de réaliser préalablement une étude bibliographique des différentes techniques de caractérisation existantes et une analyse fine de l’état de l’art. Une synthèse de cette étude sera à produire.

Laboratoire d’accueil et lieux des travaux :
Le doctorant ou la doctorante sera accueilli et réalisera ses travaux dans les locaux du laboratoire CROMA, sur le site du Bourget du Lac (UMR CNRS 5130, Bâtiment Chablais, 21 rue du lac de la Thuile, 73376 Le Bourget du Lac).
Il sera amené à se déplacer au sein de l’entreprise STMicroelectronics (12 Rue Horowitz, 38000 Grenoble) pour participer à l’élaboration (conception et fabrication) de dispositifs et échantillons de test. Dans le cadre de la collaboration avec STMicroelectronics, l’entreprise aura donc la charge de fournir tous les véhicules de test nécessaires à l’analyse des résines de moulage.

Rayonnement scientifique :
Le doctorant ou la doctorante s’impliquera dans la valorisation des résultats obtenus en les présentant dans des congrès nationaux et internationaux.

Formation du doctorant :
Le doctorant ou la doctorante suivra une formation sur la prise en main du logiciel de simulation électromagnétique Ansys HFSS, ainsi que celle qui traite des techniques de mesure hyperfréquence sur les équipements disponibles au laboratoire.

Équipements expérimentaux utilisés :
Le site du Bourget du Lac est équipé d’une plateforme de mesure hyperfréquence qui inclut (entre autres) :

• •  Un analyseur vectoriel de réseaux Keysight PNA-X N5247A (4 ports jusque 67 GHz, avec extension 110 GHz sur 2 ports).
  • Une station de mesure sous pointes Elite 300 pour mesure C. I. sur Wafer 200 et 300 mm
  • Pour les besoins de rétro-simulations, un profilomètre KLA D500 est aussi à disposition pour obtenir les grandeurs géométriques réelles des dispositifs mesurés.

Profil recherché :

• Niveau d’étude : Master 2R ou Ingénieur en électronique et Radiofréquence.
• Compétences :
  * Connaissances requises sur l’électromagnétisme, les circuits hautes fréquence.
  * Connaissances appréciées sur la physique des matériaux diélectriques et magnétiques, les logiciels de simulation électromagnétique (tels que HFSS, CST, ADS) et les appareils de mesure radiofréquence (tels que VNA : Vector Network Analyzer).
  *Une maîtrise de la langue anglaise sera appréciée

Expériences : une expérience (stage, projet d’études, …) dans le domaine RF sera appréciée.

Pour candidater :
Envoyez-nous votre CV et lettre de motivation avant le 30/06/2024. La thèse peut démarrer au plus tard le 01/11/2024.

Inscription et salaire :
Le doctorant ou la doctorante s’inscrira à l’école doctorale EEATS et recevra une rémunération mensuelle de 2300€ bruts durant ses 3 années de thèse.

Publications en lien avec ce travail :
[1] https://doi.org/10.1016/j.mejo.2021.104990
[2] https://doi.org/10.1109/SaPIW.2018.8401670
[3] http://dx.doi.org/10.1109/TIM.2006.884283

Contacts :
Gregory Houzet , 04-79-75-81-59, gregory.houzet@univ-smb.fr
Thierry Lacrevaz, 04-79-75-87-46  thierry.lacrevaz@univ-smb.fr

Université Savoie Mont Blanc
Laboratoire CROMA, UMR CNRS 5130, Bâtiment le Chablais
21 rue du lac de la Thuile
73376 Le Bourget du Lac Cedex FRANCE

• Keywords : Engineering sciences, Electronics and microelectronics - Optoelectronics, CROMA, FMNT
• Laboratory : CROMA / FMNT
• CEA code : CROMA-DHREAMS-01-30-2024
• Contact : gregory.houzet@univ-smb.fr