Materials Map

Discover the materials research landscape. Find experts, partners, networks.

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The Materials Map is an open tool for improving networking and interdisciplinary exchange within materials research. It enables cross-database search for cooperation and network partners and discovering of the research landscape.

The dashboard provides detailed information about the selected scientist, e.g. publications. The dashboard can be filtered and shows the relationship to co-authors in different diagrams. In addition, a link is provided to find contact information.

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Materials Map under construction

The Materials Map is still under development. In its current state, it is only based on one single data source and, thus, incomplete and contains duplicates. We are working on incorporating new open data sources like ORCID to improve the quality and the timeliness of our data. We will update Materials Map as soon as possible and kindly ask for your patience.

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Naji, M.
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in Cooperation with on an Cooperation-Score of 37%

Topics

Publications (30/30 displayed)

  • 2024Degradation mechanisms in PBSAT nets immersed in seawater7citations
  • 2024Basalt fibre degradation in seawater and consequences for long term composite reinforcement12citations
  • 2024Basalt fibre degradation in seawater and consequences for long term composite reinforcement12citations
  • 2024Compression and hydrothermal ageing after impact of carbon fibre reinforced epoxy laminates3citations
  • 2023Non-Arrhenian Hydrolysis of Polyethylene Terephthalate – a 5-year Long Aging Study Above and Below The Glass Transition Temperature7citations
  • 2022Hydrolytic degradation of biodegradable poly(butylene adipate-co-terephthalate) (PBAT) - Towards an understanding of microplastics fragmentation48citations
  • 2022Hydrolytic degradation of biodegradable poly(butylene adipate-co-terephthalate) (PBAT) - Towards an understanding of microplastics fragmentation48citations
  • 2022Material and structural testing to improve composite tidal turbine blade reliability10citations
  • 2022Chemical coupling between oxidation and hydrolysis in Polyamide 6 - A key aspect in the understanding of microplastic formation29citations
  • 2022Chemical coupling between oxidation and hydrolysis in Polyamide 6 - A key aspect in the understanding of microplastic formation29citations
  • 2022Fracture test to accelerate the prediction of polymer embrittlement during aging – Case of PET hydrolysis11citations
  • 2022Fracture test to accelerate the prediction of polymer embrittlement during aging – Case of PET hydrolysis11citations
  • 2021Origin of embrittlement in Polyamide 6 induced by chemical degradations: mechanisms and governing factors29citations
  • 2021Origin of embrittlement in Polyamide 6 induced by chemical degradations: mechanisms and governing factors29citations
  • 2020Fatigue of improved polyamide mooring ropes for floating wind turbines30citations
  • 2019Carbon/polyamide 6 thermoplastic composite cylinders for deep sea applications32citations
  • 2019Carbon/polyamide 6 thermoplastic composite cylinders for deep sea applications32citations
  • 2019Mechanical Behaviour of Composites Reinforced by Bamboo Strips, Influence of Seawater Aging2citations
  • 2019Compréhension de la formation des Microplastiques : Impact de l’hydrolyse du polyamide 6 sur les propriétés à la rupturecitations
  • 2019Thermoplastic matrix composites for marine applications32citations
  • 2019Comportement Mécanique de Composites Renforcés de Lamelles de Bambou, Influence du Vieillissement dans l’Eau de Mer ; Mechanical Behaviour of Composites Reinforced by Bamboo Strips, Influence of Seawater Aging2citations
  • 2019Fatigue Behaviour of Acrylic Matrix Composites: Influence of Seawater45citations
  • 2019Impact of hydrolytic degradation on mechanical properties of PET - Towards an understanding of microplastics formation128citations
  • 2018Residual Strains using Integrated Continuous Fiber Optic Sensing in Thermoplastic Composites and Structural Health Monitoring19citations
  • 2018Durability of Polymers and Composites: The Key to Reliable Marine Renewable Energy Production2citations
  • 2017Yield stress changes induced by water in polyamide 6: Characterization and modeling77citations
  • 2016Modelling the non Fickian water absorption in polyamide 657citations
  • 2016Thermoplastic Composites for Underwater Applicationscitations
  • 2016Effect of sea water and humidity on the tensile and compressive properties of carbon-polyamide 6 laminates104citations
  • 2015Thermoplastic matrix composites for underwater applicationscitations

Places of action

Chart of shared publication
Esther, Savina
1 / 1 shared
Vincent, Benoît
2 / 2 shared
Gué, Louis Le
1 / 1 shared
Nicolas, Gayet
1 / 1 shared
Davies, Peter
20 / 131 shared
Wouter, Verbouwe
1 / 1 shared
Louis, Le Gué
1 / 1 shared
Verbouwe, Wouter
1 / 1 shared
Le Gué, Louis
1 / 1 shared
Vincent, Benoit
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Gangadhara Prusty, B.
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Caldwell, Rowan
1 / 1 shared
Gac, Pierre Yves Le
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Maelenn, Le Gall
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Priour, Daniel
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Dreanno, Catherine
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Deshoulles, Quentin
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Le Gall, Maelenn
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Cerantola, S.
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Le Gac, Pierre Yves
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Raquez, J-M.
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Stoclet, Grégory
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Benali, S.
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Stoclet, G.
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Quentin, Deshoulles
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Paboeuf, Stephane
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Mayorga, Pedro
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Dumergue, Nicolas
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Nicolas, Erwann
1 / 1 shared
Le Gall, M.
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Yoan, Chevillotte
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Yann, Marco
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Guilhem, Bles
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Karel, Devos
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Mathieu, Keryer
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Christian, Burtin
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Christophe, Briancon
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Briancon, Christophe
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Burtin, Christian
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Guillaume, Kemlin
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Kemlin, Guillaume
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Penumadu, D.
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Meek, N.
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Garg, N.
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Corentin, Humeau
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Chart of publication period
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Co-Authors (by relevance)

  • Esther, Savina
  • Vincent, Benoît
  • Gué, Louis Le
  • Nicolas, Gayet
  • Davies, Peter
  • Wouter, Verbouwe
  • Louis, Le Gué
  • Verbouwe, Wouter
  • Le Gué, Louis
  • Vincent, Benoit
  • Gangadhara Prusty, B.
  • Caldwell, Rowan
  • Gac, Pierre Yves Le
  • Maelenn, Le Gall
  • Priour, Daniel
  • Dreanno, Catherine
  • Deshoulles, Quentin
  • Le Gall, Maelenn
  • Cerantola, S.
  • Le Gac, Pierre Yves
  • Raquez, J-M.
  • Stoclet, Grégory
  • Benali, S.
  • Stoclet, G.
  • Quentin, Deshoulles
  • Paboeuf, Stephane
  • Mayorga, Pedro
  • Dumergue, Nicolas
  • Nicolas, Erwann
  • Le Gall, M.
  • Yoan, Chevillotte
  • Yann, Marco
  • Guilhem, Bles
  • Karel, Devos
  • Mathieu, Keryer
  • Christian, Burtin
  • Christophe, Briancon
  • Briancon, Christophe
  • Burtin, Christian
  • Guillaume, Kemlin
  • Kemlin, Guillaume
  • Penumadu, D.
  • Meek, N.
  • Garg, N.
  • Corentin, Humeau
OrganizationsLocationPeople

document

Compréhension de la formation des Microplastiques : Impact de l’hydrolyse du polyamide 6 sur les propriétés à la rupture

  • Gac, Pierre Yves Le
  • Priour, Daniel
  • Dreanno, Catherine
  • Quentin, Deshoulles
  • Maelenn, Le Gall
  • Davies, Peter
  • Arhant, Mael
Abstract

La pollution de l’environnement marin par les microplastiques (MP), particules de taille inférieure à 5 mm (Arthur et al., 2009) est devenue une préoccupation mondiale (Cole et al., 2011; Wright et al., 2013). Les mécanismes de formation par fragmentation des macroplastiques sont aujourd’hui mal compris. La compréhension passe par le vieillissement accéléré de matériaux en laboratoire. Un polymère thermoplastique sensible à l’oxygène et à l’eau a été considéré dans cette étude. Le polyamide 6 en film mince de 250 µm d’épaisseur a été utilisé. Les vieillissements ont été découplés pour rendre compte de la part que joue chaque phénomène dans la dégradation. Dans cette étude, seul le phénomène d’hydrolyse a été traité pour en quantifier son effet dans la dégradation du polyamide 6 en milieu marin. Pour l’accélération du vieillissement des températures, entre 80°C et 140°C ont été utilisés avec des durées de vieillissement allant jusqu’à 400 jours. Les échantillons ont ensuite été caractérisés afin d'identifier les évolutions observées aux différentes échelles (spectroscopie IR-ATR, Calorimétrie différentielle à balayage, Chromatographie par Perméation de Gel, test de traction et Microscopie Electronique à Balayage). Les observations ont montré une baisse de la masse moléculaire ainsi qu’une augmentation du taux de cristallinité. Les tests de traction ont révélé une fragilisation du matériau conduisant à une chute de la contrainte maximale. Les évolutions de structure ont ensuite été confrontées aux évolutions de propriétés mécaniques pour définir un critère de transition ductile-fragile du matériau (Arhant et al., 2019).     Références   Arhant, M., Le Gall, M., Le Gac, P.-Y., Davies, P., 2019. Impact of hydrolytic degradation on mechanical   properties of PET - Towards an understanding of microplastics formation. Polymer Degradation and Stability. https://doi.org/10.1016/j.polymdegradstab.2019.01.021 Arthur, C., Jeol E., B., Bamford, H.A., 2009. Proceedings of the International Research Workshop on the Occurrence, Effects, and Fate of Microplastic Marine Debris 2008. University of Washington Tacoma, Tacoma, WA, USA. Cole, M., Lindeque, P., Halsband, C., Galloway, T.S., 2011. Microplastics as contaminants in the marine environment: A review. Marine Pollution Bulletin 62, 2588–2597. https://doi.org/10.1016/j.marpolbul.2011.09.025 Wright, S.L., Thompson, R.C., Galloway, T.S., 2013. The physical impacts of microplastics on marine organisms: A review. Environmental Pollution 178, 483–492. https://doi.org/10.1016/j.envpol.2013.02.031

Topics
  • polymer
  • laser emission spectroscopy