Your search keyword '"Nathanaël Guigo"' showing total 11 results

1. Crystallization of Polytetrafluoroethylene in a Wide Range of Cooling Rates: Nucleation and Diffusion in the Presence of Nanosilica Clusters

Author

Nicolas Bosq, Nathanaël Guigo, Jacques Persello, and Nicolas Sbirrazzuoli

Subjects

polytetrafluoroethylene, silica, nanocomposite, crystallization kinetics, isoconversional analysis, Organic chemistry, QD241-441

Abstract

Polytetrafluoroethylene (PTFE) is a polymer that displays exceptional properties. This synthetic fluoropolymer is also known to crystallize very fast upon cooling. The present work highlights for the first time the influence of nanosilica clusters on PTFE crystallization at fast cooling rates (up to 5000 K·s−1). The silica was synthesized from aqueous silicate solution and the surface modification was performed using TriEthoxyFluoroSilane (TEFS). In order to understand the crystallization behavior of PTFE/silica nanocomposite at a fast cooling rate, the measurements were carried out by Fast Scanning Calorimetry (FSC). The data were consequently combined with the measurements performed by conventional Differential Scanning Calorimetry (DSC). Interestingly, the results displayed variation of the crystallization behavior for the nanocomposite at fast cooling rates compared to slow cooling rates. The differences in crystal morphologies were then observed by Scanning Electron Microscopy (SEM) after slow and fast cooling rates. Finally, the effective activation energies (Eα) obtained from the crystallization under various cooling rates were combined in order to obtain one set of Hoffman-Lauritzen parameters. This procedure allowed us to show that the crystallization of PTFE in the presence of silica is promoted or hampered according to the cooling rates employed.

Published

2019

2. Mechanical Behaviour and Induced Microstructural Development upon Simultaneous and Balanced Biaxial Stretching of Poly(ethylene furandicarboxylate), PEF

Author

Emilie Forestier, Christelle Combeaud, Nathanaël Guigo, and Nicolas Sbirrazzuoli

Subjects

Polymers and Plastics, biaxial stretching, microstructural development, General Chemistry, Polyethylene 2,5-furandicarboxylate, strain-induced crystallization (SIC)

Abstract

The biaxial behavior of PEF has been analyzed for equilibrated and simultaneous biaxial stretching. The ability of PEF to develop an organized microstructure through strain induced crystallization (SIC) has been described. Upon biaxial stretching, SIC can be difficult to perform because the stretching is performed in two perpendicular directions. However, thanks to the time/temperature superposition principle and an accurate heating protocol, relevant stretching settings have been chosen to stretch the material in its rubbery-like state and to reach high levels of deformation. By the protocol applied, the mechanical behavior is easily transposable to the industry. This work has shown that PEF can, as in uniaxial stretching, develop well-organized crystals and a defined microstructure upon biaxial stretching. This microstructure allows the obtention of improved mechanical properties and thermal stability of the biaxially stretched samples. The crystals induced upon biaxial stretching are similar to the one that has been developed and observed after uniaxial stretching and upon static crystallization. Moreover, the furan cycles seem to appear in a state similar to the one of a sample crystallized upon quiescent condition. The rigidity is increased, and the α-relaxation temperature is increased by 15 °C.

Published

2023

3. Cationic UV Curing of Bioderived Epoxy Furan-Based Coatings: Tailoring the Final Properties by In Situ Formation of Hybrid Network and Addition of Monofunctional Monomer

Author

Lorenzo Pezzana, Giuseppe Melilli, Nathanaël Guigo, Nicolas Sbirrazzuoli, and Marco Sangermano

Subjects

5-Furandimethanol, 2,5-Furandimethanol, Biobased, Cationic UV curing, Epoxy, Renewable Energy, Sustainability and the Environment, General Chemical Engineering, Environmental Chemistry, General Chemistry

Published

2021

4. Tuning conditions for the amine-functionalization of carbonyls formed in biobased polyfurfuryl alcohol

Author

Pierre Delliere and Nathanael Guigo

Subjects

Poly(furfurylalcohol), Biobased thermoset, Amine-functionalization, Structure/property relations, Science (General), Q1-390

Abstract

Biobased furan resins (furfuryl alcohol based) are functionalized by taking advantage of a side-reaction occurring during its polymerization. The furan ring-opening reactions yields carbonyls which can be functionalized by reaction with primary amines. Light is shed on unexplored parameters impacting the properties of PFA/Amine systems. First, PFA/Amines were prepared using PFA resins at conversion degree between 0.3 and 0.95. Overall, high conversion degrees (0.9 and above) are best suited to produce rigid materials. In addition, a precipitation process may be used to reach high Tg biobased materials (145 °C). Finally, the impact of the amines’ basicity on the properties of PFA/Amines was investigated. The results highlighted that PFAs at conversion degrees above 0.9 are little affected by the basicity. However, the properties of PFA functionalized at lower conversion degrees are strongly affected by the bases, i.e. high brittleness. This can be circumvented by limiting the functionalization degree to 0.25 and below.

Published

2024

5. Impact of amine functionalization on poly(furfuryl alcohol) properties

Author

Pierre Delliere, Pierre Antonczak, and Nathanael Guigo

Subjects

Biobased thermoset, Flexibilization, Thermal degradation, Oxidation, Polymers and polymer manufacture, TP1080-1185

Abstract

Polyfurfuryl alcohol (PFA) is a biobased thermoset with high stiffness. As carbonyls are formed via furan ring opening during polymerization, their inevitable presence was exploited to tune the PFA properties. Various diamines were employed to react with these carbonyls and consequence on thermal and mechanical properties were evaluated. Short and rigid diamines and long and flexible diamines were respectively selected for this functionalization. The more rigid amines lead to an increase of the Tg of the material compared to the pristine PFA but the ultimate properties were not particularly improved. Flexible polyetheramines such as Jeffamine D-2000 (J2000) combined with PFA allows the formation of a flexible elastomeric network (Tg = −44 °C) presenting high thermal stability due to the presence of the thermally stable furanic chains. For PFA/J2000 samples, a rigid crust is formed in oxidative conditions at T > 175 °C when the PFA content is relatively important (>50 % w/w). This phenomenon is massively impacting the ultimate mechanical properties and the thermal stability.

Published

2023

6. Natural fibre composites with furanic thermoset resins. Comparison between polyfurfuryl alcohol and humins from sugar conversion

Author

Anna Sangregorio, Anitha Muralidhara, Nathanael Guigo, Guy Marlair, Ed de Jong, and Nicolas Sbirrazzuoli

Subjects

Biobased thermosets, Biorefinery co-products, Wettability, Fire hazard, Furanic resins, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Industrial humins from biorefining process of sugars were used as reactive thermoset matrix for the preparation of humins-jute fibre composites. This material was investigated and benchmarked with jute composites prepared with polyfurfurylalcohol (PFA), a well-known biobased thermosetting resin The Dynamic Mechanical Analyses (DMA) showed glass transition temperature (Tg) associated to the relaxation of the cross-linked humins’ chains at 75 °C similar to the Tg of PFA. The two types of composites revealed tensile properties in the same range and both materials demonstrated very low water uptake and good dimensional stability after immersion in liquid water. Such higher hydrophobicity compared to raw jute mat is the consequence of the good interfacial interaction of both furanic matrix with the jute fibres in agreement with SEM observations. Fire performance of materials was also investigated, demonstrating that the fire hazard of composites was not increased by the presence of furanic matrix. Interestingly, humins composites were slightly better than PFA composites for both the thermal and fire-induced toxicity threats. This study demonstrated the possibility of using industrial humins instead of PFA as a thermoset-like resin for the next generation of biobased composites.

Published

2021

7. Conditions to Control Furan Ring Opening during Furfuryl Alcohol Polymerization

Author

Lucie Quinquet, Pierre Delliere, and Nathanael Guigo

Subjects

biobased poly(furfuryl alcohol), ring-opening, degree of open structures, Organic chemistry, QD241-441

Abstract

The chemistry of biomass-derived furans is particularly sensitive to ring openings. These side reactions occur during furfuryl alcohol polymerization. In this work, the furan ring-opening was controlled by changing polymerization conditions, such as varying the type of acidic initiator or the water content. The degree of open structures (DOS) was determined by quantifying the formed carbonyl species by means of quantitative 19F NMR and potentiometric titration. The progress of polymerization and ring opening were monitored by DSC and FT-IR spectroscopy. The presence of additional water is more determining on ring opening than the nature of the acidic initiator. Qualitative structural assessment by means of 13C NMR and FT-IR shows that, depending on the employed conditions, poly(furfuryl alcohol) samples can be classified in two groups. Indeed, either more ester or more ketone side groups are formed as a result of side ring opening reactions. The absence of additional water during FA polymerization preferentially leads to opened structures in the PFA bearing more ester moieties.

Published

2022

8. A Perspective on PEF Synthesis, Properties, and End-Life

Author

Katja Loos, Ruoyu Zhang, Inês Pereira, Beatriz Agostinho, Han Hu, Dina Maniar, Nicolas Sbirrazzuoli, Armando J. D. Silvestre, Nathanael Guigo, and Andreia F. Sousa

Subjects

PEF, poly(ethylene 2,5-furandicarboxylate), 2,5-furandicarboxylic acid, green synthesis, biodegradation, nanomaterials, Chemistry, QD1-999

Abstract

This critical review considers the extensive research and development dedicated, in the last years, to a single polymer, the poly(ethylene 2,5-furandicarboxylate), usually simply referred to as PEF. PEF importance stems from the fact that it is based on renewable resources, typically prepared from C6 sugars present in biomass feedstocks, for its resemblance to the high-performance poly(ethylene terephthalate) (PET) and in terms of barrier properties even outperforming PET. For the first time synthesis, properties, and end-life targeting—a more sustainable PEF—are critically reviewed. The emphasis is placed on how synthetic roots to PEF evolved toward the development of greener processes based on ring open polymerization, enzymatic synthesis, or the use of ionic liquids; together with a broader perspective on PEF end-life, highlighting recycling and (bio)degradation solutions.

Published

2020

9. Opening furan for tailoring properties of biobased poly(furfuryl alcohol) thermoset

Author

Guillaume Falco, Nathanaël Guigo, Luc VINCENT, Nicolas Sbirrazzuoli, Institut de Chimie de Nice (ICN), Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université Côte d'Azur (UCA), and Vincent, Luc

Subjects

[CHIM.MATE] Chemical Sciences/Material chemistry, [CHIM.MATE]Chemical Sciences/Material chemistry, ComputingMilieux_MISCELLANEOUS

Abstract

International audience

10. Valorisation of biorefinery-derived humins : towards the development of sustainable thermosets and composites

Author

Sangregorio, Anna, Institut de Chimie de Nice (ICN), Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université Côte d'Azur (UCA), COMUE Université Côte d'Azur (2015 - 2019), Nicolas Sbirrazzuoli, Nathanaël Guigo, and STAR, ABES

Subjects

Biomass valorisation, Valorisation de la biomasse, [CHIM.MATE] Chemical Sciences/Material chemistry, Humines, Biobased materials, [CHIM.MATE]Chemical Sciences/Material chemistry, Matériaux bio-sourcés, Humins, Composites

Abstract

The production of chemicals via acid-catalysed dehydration of sugars is inevitably related to the formation of co-products. Noteworthy, a black and viscous polymeric co-product called humins can be formed in significant quantities. Humins are heterogeneous and polydisperse macromolecules, mainly constituted by furanic rings and aldehydes, ketones and hydroxyls as main functional groups. For many years, scientists focused on finding a way to avoid humins formation during biorefinery processes but that appears to be almost inevitable. In current biorefinery process designs, humins are burnt to generate heat that can be integrated back into the process. However, the attention is now shifting towards ways to make high value-added products from humins, to further improve the process economics of biorefineries. An extensive analysis of the structure and pysico-chemical properties of humins was performed to support humins application research. Particular attention was paid to the identification of transitions and chemical reactions occurring in humins, by using advanced thermoanalytical techniques. It was demonstrated that it is possible to obtain a thermoset polymer with different properties, based on the treatment used. The cross-linking behaviour was then further elucidated by studying optimal initiators and through a deep investigation on the kinetics of cross-linking. Humin based thermosets were tested for different applications. The potential of all-humins-matrix in combination with natural fibres was investigated. Good interaction between organic matrix and natural fibres was observed, making humins very promising for the next generation of biobased thermoset materials. The use of humins as matrix is a sustainable solution to develop all "green" composites, with high hydrophobic properties and mechanical properties comparable with other biobased thermosets used in several commercial applications. Considering the very good affinity with lignocellulosic materials, a new process option was evaluated for fibre modification to enhance the interaction at the interface between cellulosic fibres and common polymeric matrices such as polypropylene. This study also allowed to get insights into the interactions between cellulose and humins. To further exploit these type of applications, wood modification with humin resin was studied. Dimension and weight stability of the modified wood after immersion in water confirmed improved hydrophobicity of the final material. Mechanical properties were studied by DMA. This study demonstrates that this new impregnation technique can improve the dimensional stability of wood, without compromising on the mechanical properties by valorising humins. Finally, the possibility to use humins as a binder to enhance bitumen’s rheological properties and decrease its environmental impact was investigated., La production de molécules plateformes via la déshydratation des sucres catalysée par un acide est inévitablement liée à la formation de sous-produits. Notamment, un sous-produit appelé humine peut être formé en quantités importantes. Les humines sont des macromolécules hétérogènes et polydisperses, constituées principalement de composés furaniques. Pendant nombreuses années, les scientifiques ont cherché à trouver un moyen d'éviter la formation d'humines au cours des processus de bioraffinage, mais cela semble presque inévitable. Les recherches actuelles se concentrent aujourd’hui sur les moyens de fabriquer des produits à haute valeur ajoutée à partir d'humines, afin d'améliorer la rentabilité des bioraffineries. Une analyse approfondie de la structure et des propriétés physico-chimiques des humines a été réalisée dans ce travail de thèse afin de développer de nouveaux axes de recherche sur les applications potentielles des humines, en particulier l'identification des transitions et des réactions chimiques se produisant dans les humines, en utilisant des techniques thermo-analytiques avancées. Il a été démontré qu'il est possible d'obtenir un polymère thermodurcissable avec différentes propriétés, en fonction du traitement utilisé. Les thermodurcissables à base d'humine ont été testés pour différentes applications. Le potentiel des humines comme matrice en combinaison avec des fibres naturelles afin de réaliser des composites 100 \% biosourcés a été étudié. Une bonne interaction entre la matrice organique et les fibres naturelles a été observée, rendant les humines très prometteuses pour la prochaine génération de matériaux et de composites thermodurcissables biosourcés. L'utilisation d'humines comme matrice est une solution durable pour développer des composites "verts", avec des propriétés hydrophobes et mécaniques élevées. Compte tenu de la très bonne affinité avec les matériaux lignocellulosiques, de nouvelles voies ont été proposées pour la modification des fibres afin de renforcer l’interaction entre les fibres cellulosiques et certaines matrices polymériques, telles que le polypropylène par exemple. Cette étude a également permis de mieux comprendre les interactions entre la cellulose et les humines. Pour exploiter ce type d’applications, la modification du bois avec des humines a été étudiée. La stabilité dans l’eau du bois modifié a confirmé l'amélioration de l'hydrophobicité du matériau final. Cette étude montre que cette nouvelle technique d'imprégnation peut améliorer la stabilité dimensionnelle du bois sans compromettre les propriétés mécaniques tout en valorisant les humines. Enfin, la possibilité d’utiliser des humines comme liant pour améliorer les propriétés rhéologiques du bitume et réduire son impact sur l’environnement a été étudiée.

Published

2019

11. Valorisation d'humines issues de biorafineries : vers le développement de thermodurcissables et de composites durables

Author

sangregorio, anna, Institut de Chimie de Nice (ICN), Université Nice Sophia Antipolis (... - 2019) (UNS), COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université Côte d'Azur (UCA), COMUE Université Côte d'Azur (2015 - 2019), Nicolas Sbirrazzuoli, and Nathanaël Guigo

Subjects

Biomass valorisation, Valorisation de la biomasse, Humines, Biobased materials, [CHIM.MATE]Chemical Sciences/Material chemistry, Matériaux bio-sourcés, Humins, Composites

Abstract

The production of chemicals via acid-catalysed dehydration of sugars is inevitably related to the formation of co-products. Noteworthy, a black and viscous polymeric co-product called humins can be formed in significant quantities. Humins are heterogeneous and polydisperse macromolecules, mainly constituted by furanic rings and aldehydes, ketones and hydroxyls as main functional groups. For many years, scientists focused on finding a way to avoid humins formation during biorefinery processes but that appears to be almost inevitable. In current biorefinery process designs, humins are burnt to generate heat that can be integrated back into the process. However, the attention is now shifting towards ways to make high value-added products from humins, to further improve the process economics of biorefineries. An extensive analysis of the structure and pysico-chemical properties of humins was performed to support humins application research. Particular attention was paid to the identification of transitions and chemical reactions occurring in humins, by using advanced thermoanalytical techniques. It was demonstrated that it is possible to obtain a thermoset polymer with different properties, based on the treatment used. The cross-linking behaviour was then further elucidated by studying optimal initiators and through a deep investigation on the kinetics of cross-linking. Humin based thermosets were tested for different applications. The potential of all-humins-matrix in combination with natural fibres was investigated. Good interaction between organic matrix and natural fibres was observed, making humins very promising for the next generation of biobased thermoset materials. The use of humins as matrix is a sustainable solution to develop all "green" composites, with high hydrophobic properties and mechanical properties comparable with other biobased thermosets used in several commercial applications. Considering the very good affinity with lignocellulosic materials, a new process option was evaluated for fibre modification to enhance the interaction at the interface between cellulosic fibres and common polymeric matrices such as polypropylene. This study also allowed to get insights into the interactions between cellulose and humins. To further exploit these type of applications, wood modification with humin resin was studied. Dimension and weight stability of the modified wood after immersion in water confirmed improved hydrophobicity of the final material. Mechanical properties were studied by DMA. This study demonstrates that this new impregnation technique can improve the dimensional stability of wood, without compromising on the mechanical properties by valorising humins. Finally, the possibility to use humins as a binder to enhance bitumen’s rheological properties and decrease its environmental impact was investigated.; La production de molécules plateformes via la déshydratation des sucres catalysée par un acide est inévitablement liée à la formation de sous-produits. Notamment, un sous-produit appelé humine peut être formé en quantités importantes. Les humines sont des macromolécules hétérogènes et polydisperses, constituées principalement de composés furaniques. Pendant nombreuses années, les scientifiques ont cherché à trouver un moyen d'éviter la formation d'humines au cours des processus de bioraffinage, mais cela semble presque inévitable. Les recherches actuelles se concentrent aujourd’hui sur les moyens de fabriquer des produits à haute valeur ajoutée à partir d'humines, afin d'améliorer la rentabilité des bioraffineries. Une analyse approfondie de la structure et des propriétés physico-chimiques des humines a été réalisée dans ce travail de thèse afin de développer de nouveaux axes de recherche sur les applications potentielles des humines, en particulier l'identification des transitions et des réactions chimiques se produisant dans les humines, en utilisant des techniques thermo-analytiques avancées. Il a été démontré qu'il est possible d'obtenir un polymère thermodurcissable avec différentes propriétés, en fonction du traitement utilisé. Les thermodurcissables à base d'humine ont été testés pour différentes applications. Le potentiel des humines comme matrice en combinaison avec des fibres naturelles afin de réaliser des composites 100 \% biosourcés a été étudié. Une bonne interaction entre la matrice organique et les fibres naturelles a été observée, rendant les humines très prometteuses pour la prochaine génération de matériaux et de composites thermodurcissables biosourcés. L'utilisation d'humines comme matrice est une solution durable pour développer des composites "verts", avec des propriétés hydrophobes et mécaniques élevées. Compte tenu de la très bonne affinité avec les matériaux lignocellulosiques, de nouvelles voies ont été proposées pour la modification des fibres afin de renforcer l’interaction entre les fibres cellulosiques et certaines matrices polymériques, telles que le polypropylène par exemple. Cette étude a également permis de mieux comprendre les interactions entre la cellulose et les humines. Pour exploiter ce type d’applications, la modification du bois avec des humines a été étudiée. La stabilité dans l’eau du bois modifié a confirmé l'amélioration de l'hydrophobicité du matériau final. Cette étude montre que cette nouvelle technique d'imprégnation peut améliorer la stabilité dimensionnelle du bois sans compromettre les propriétés mécaniques tout en valorisant les humines. Enfin, la possibilité d’utiliser des humines comme liant pour améliorer les propriétés rhéologiques du bitume et réduire son impact sur l’environnement a été étudiée.

Published

2019