Phd Position - New Inorganic-Polymer Composite Materials For The Positive Electrode Of Asymmetric...

Universities and Institutes of France


October 3, 2022


  • Organisation/Company: ICMCB Bordeaux - CNRS
  • Research Field: Chemistry Physics Technology › Energy technology
  • Researcher Profile: First Stage Researcher (R1) Recognised Researcher (R2) Established Researcher (R3) Leading Researcher (R4)
  • Application Deadline: 03/10/2022 00:00 - Europe/Brussels
  • Location: France › Bordeaux
  • Type Of Contract: Temporary
  • Job Status: Full-time
  • DEADLINE: 22/09/22

    Supercapacitors are high power energy storage devices that are able to fulfill specific energy storage/harvesting application requirements in the fields of space, aircrafts, transportation and smart grids. The involvement into the smart grides is particularly important to take the best benefit of the intermittent renewable energies provided by sun or wind. An important research line, aiming at increasing both energy and power densities, is devoted to asymmetric devices including a transition metal oxide based electrode (positive electrode) and an activated carbon based (C) electrode (negative electrode). Among them, the MnO2/C system is the most promising since it withstands hundreds of thousands of cycles, exhibits low cost and is environmental friendly - especially because of the aqueous based electrolyte used in such devices. Nevertheless, Mn02 suffers from both poor electronic and ionic conductivity, which limits the perfomances between the pseudo-capacitive properties brought by MnO2 and the excellent ionic and electronic conductivity properties of ambivalent copolymers. These nanocomposites which will be subsequently put in form as electrodes, or directly developed as monolithic all in one electrodes, meeting the requirements of high power cycling of supercapacitors.

    This project gathers 2 fully complementary partners, ICMCB and LCPO, which are expert in the field of inogarnic materials for energy storage devices, and conductive polymers respectively, and will ensure the co-direction of the thesis, thus fitting with the multdisciplinary approach of the project. IPREM (Delphine Flahaut, Univ Pau) and CIRIMAT (Pierre Louis Taberna, Toulouse) will be inserted in the consortium, for advanced characterization of the materials: surface and inorganic-polymer interface characterization (XPS, Auger) for IPREM and Electrochemical Impedance Spectroscopy as well as Ultramicroelectrode for CIRIMAT.

    The beginning of the thesis is planned on January, 1st 2023 at the latest and for a duration of 3 years.

    This topic is part of the European project DESTINY, Doctorate programme on Emerging battery Storage Technologies INspiring Young scientists (https: // www., which aims at creating a new paradigm change in battery research. CNRS, acting as the coordinator, with 42 European partner institutions working on future batteries and related issues on energy storage, committed to ambitiously participate in the long-term research initiative Battery 2030+. The project consists in delivering a competitive edge to European industry and academy within the rapidly emerging green technology areas of Electro-mobility and Large-scale energy storage.

    Grading institution: Université de Bordeaux - FRANCE / Recruiting organisation: CNRS – FRANCE / Hosting: ICMCB Bordeaux – FRANCE / Co-funding organisation: Région Nouvelle Aquitaine - FRANCE / Secondment foreseen: CIRIMAT Toulouse - FRANCE & IPREM PAU - FRANCE / PhD Supervisors: GUERLOU- DEMOURGUES Liliane (ICMCB) & BROCHON Cyril (LCPO)

    Funding category: Contrat doctoral


    PHD Country: France

    Offer Requirements Specific Requirements


    • Please read carefully the Guide for Applicants on the DESTINY website which explains the eligibility requirements and the Application Form N°1 and N°2 with the supporting documents to be provided: https: // www. destiny- • Please upload your Application Form N°1 in PDF in the CV box and your Application Form N°2 in PDF in the cover letter box. • Please disregard the "Application deadline" next to the "apply" button at the top of the advert, the real date is the one indicated on the DESTINY website: https: // www. • Please do not consider in the salary value indicated for the "Remuneration" & see the Guide for Applicants for more information. • If you apply to the other offer of DESTINY Cohort#2 in the CNRS job portal entitled " PhD Position: New inorganic-polymer composite materials for the positive electrode of asymmetric supercapacitors – DESTINY Marie Sklodowska- Curie Actions COFUND - PhD PROGRAMME ", the Application Forms N°1 & N°2 can be the same (specify the 2 topics chosen in section 3 of the Application Form N°2).

    Contact Information
  • Organisation/Company: ICMCB Bordeaux - CNRS
  • Organisation Type: Public Research Institution
  • Website: https: // www.
  • Country: France
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