, European Commission, Reducing CO2 emissions from passenger cars, 2017.

, Average carbon dioxide emissions from new passenger cars, 2017.

, No improvements on average CO2 emissions from new cars in 2017, 2018.

, The french automotive industry -Analysis & Statistics, 2016.

A. Ulman, An Introduction To Ultrathin Organic Films: From Langmuir-Blodgett To SelfAssembly, 1991.

E. Smith and W. Chen, How To Prevent the Loss of Surface Functionality Derived from Aminosilanes, Langmuir, vol.24, pp.12405-12409, 2008.

M. Zhu, M. Z. Lerum, and W. Chen, How To Prepare Reproducible, Homogeneous, and Hydrolytically Stable Aminosilane-Derived Layers on Silica, Langmuir, vol.28, pp.416-423, 2012.

J. Canning, I. Petermann, and K. Cook, Surface treatment of silicate based glass: base Piranha treatment versus 193nm laser processing, Asia Pacific Optical Sensors Conference, 2012.

D. L. Allara, A. N. Parikh, and F. Rondelez, Evidence for a Unique Chain Organization in Long Chain Silane Monolayers Deposited on Two Widely Different Solid Substrates, Langmuir, vol.11, pp.2357-2360, 1995.

E. Felder, Surfaces, tribologie et formage des matériaux: mélanges offerts à François Delamare pour son 60e anniversaire, Presses des MINES, 2001.

R. Chepyala and S. Panda, Tunable surface free energies of functionalized molecular layers on Si surfaces for microfluidic immunosensor applications, Appl. Surf. Sci, vol.271, pp.77-85, 2013.

K. B. Lim and D. C. Lee, Surface modification of glass and glass fibres by plasma surface treatment, Surface and Interface Analysis, vol.36, pp.254-258, 2004.

K. Sever, Y. Seki, I. H. Tavman, G. Erkan, and V. Cecen, The Structure of ?-glycidoxypropyltrimethoxysilane on glass fiber surfaces: characterization by FTIR, SEM, and contact angle measurements, Polym. Compos, vol.30, pp.550-558, 2009.

S. G. Turrión, D. Olmos, and J. González-benito, Complementary characterization by fluorescence and AFM of polyaminosiloxane glass fibers coatings, Polymer Testing, vol.24, pp.301-308, 2005.

X. M. Liu, J. L. Thomason, and F. R. Jones, Differentiation of silane adsorption onto model Eglass surfaces from mixed solutions of amino and glycidyl silanes, Silanes and Other Coupling Agents, pp.17-28, 2007.

F. R. Jones, X. M. Liu, and J. L. Thomason, The differential adsorption of silanes from solution onto model E-glass surfaces using high resolution XPS, 5th International Symposium on Silanes and Other Coupling Agents, 2005.

A. Mikdam, Nouveaux matériaux composites à matrice thermoplastique : étude des interfaces, Laboratoire Avancé Innovation Matériaux LAIM, Rhodia, centre de recherches et technologies de Lyon, 2012.

D. J. Ireland, J. G. Nel, and R. G. Keske, Aqueous-based polyamide-amic acid compositions, pp.6479581-6479582, 2002.

C. Clegg, Contact Angle Made Easy, 2013.

I. Chapitre and . Méthodes,

J. L. Thomason, Glass Fibre Sizings: A review of the scientific literature, 2015.

J. L. Thomason and L. J. Adzima, Sizing up the interphase: an insider's guide to the science of sizing, Compos. Pt. A-Appl. Sci. Manuf, vol.32, pp.313-321, 2001.

H. N. Petersen, Y. Kusano, P. Brøndsted, and K. , Preliminary characterization of glass fiber sizing, Risoe International Symposium on Materials Science. Proceedings, pp.333-340, 2013.

S. Keusch, H. Queck, and K. Gliesche, Influence of glass fibre/epoxy resin interface on static mechanical properties of unidirectional composites and on fatigue performance of cross ply composites, Composites Part A: Applied Science and Manufacturing, vol.29, pp.701-705, 1998.

M. Dey, J. M. Deitzel, J. W. Gillespie, and S. Schweiger, Influence of sizing formulations on glass/epoxy interphase properties, Composites Part A: Applied Science and Manufacturing, vol.63, pp.59-67, 2014.

S. Rudzinski, L. Häussler, C. H. Harnisch, E. Mäder, and G. Heinrich, Glass fibre reinforced polyamide composites: Thermal behaviour of sizings, Composites Part A: Applied Science and Manufacturing, vol.42, pp.157-164, 2011.

L. Peters, Influence of Glass Fibre Sizing and Storage Conditions on Composite Properties, Durability of Composites in a Marine Environment, pp.19-31, 2018.

Z. Boufaida, L. Farge, S. André, and Y. Meshaka, Influence of the fiber/matrix strength on the mechanical properties of a glass fiber/thermoplastic-matrix plain weave fabric composite, Composites Part A: Applied Science and Manufacturing, vol.75, pp.28-38, 2015.
URL : https://hal.archives-ouvertes.fr/hal-01297302

V. Cech, A. Knob, H. Hosein, A. Babik, P. Lepcio et al., Enhanced interfacial adhesion of glass fibers by tetravinylsilane plasma modification, Compos. Pt. A-Appl. Sci. Manuf, vol.58, pp.84-89, 2014.

F. R. Jones, A Review of Interphase Formation and Design in Fibre-Reinforced Composites, Journal of Adhesion Science and Technology, vol.24, pp.171-202, 2010.

J. Canning, I. Petermann, and K. Cook, Surface treatment of silicate based glass: base Piranha treatment versus 193nm laser processing, Asia Pacific Optical Sensors Conference, 2012.

D. Ochs, S. Dieckhoff, and B. Cord, Characterization of hard disk substrates (NiP/Al, glass) using XPS, Surf. Interface Anal, vol.30, pp.12-15, 2000.

K. Sever, M. Sarikanat, Y. Seki, and I. H. Tavman, Concentration effect of ?-glycidoxypropyltrimethoxysilane on the mechanical properties of glass fiber-epoxy composites, Polym Compos, vol.30, pp.1251-1257, 2009.

, Chapitre III -Étude comparative de différents agents filmogènes de type PU

D. Wang and F. R. Jones, ToF-SIMS and XPS studies of the interaction of silanes and matrix resins with glass surfaces, Surf. Interface Anal, vol.20, pp.457-467, 1993.

S. G. Turrión, D. Olmos, and J. González-benito, Complementary characterization by fluorescence and AFM of polyaminosiloxane glass fibers coatings, Polymer Testing, vol.24, pp.301-308, 2005.

J. G. Iglesias, J. González-benito, A. J. Aznar, J. Bravo, and J. Baselga, Effect of glass fiber surface treatments on mechanical strength of epoxy based composite materials, J Colloid Interface Sci, vol.250, pp.251-260, 2002.

S. Feih, A. Thraner, and H. Lilholt, Tensile strength and fracture surface characterisation of sized and unsized glass fibers, J Mater Sci, vol.40, pp.1615-1623, 2005.

G. Ozkoc, G. Bayram, and E. Bayramli, Effects of polyamide 6 incorporation to the short glass fiber reinforced ABS composites: an interfacial approach, Polymer, vol.45, pp.8957-8966, 2004.

M. C. Bautista, J. Rubio, and J. L. Oteo, Surface Thermodynamic Analysis of Cleaned Silicoaluminate Glass-Fibers, J. Mater. Sci, vol.30, pp.1595-1600, 1995.

X. M. Liu, J. L. Thomason, and F. R. Jones, The concentration of hydroxyl groups on glass surfaces and their effect on the structure of silane deposits, Silanes and Other Coupling Agents, vol.5, pp.25-38, 2009.

B. Li, Y. Zhang, and G. Wu, Thermoplastics reinforced by self-welded glass fibers: effect of interfacial affinity on preferential segregation, Polymer, vol.54, pp.2440-2449, 2013.

H. Salehi-mobarakeh, J. Brisson, and A. Ait-kadi, Polym Compos, vol.19, pp.264-274, 1998.

C. Clegg, Contact Angle Made Easy, 2013.

D. K. Owens and R. C. Wendt, Estimation of the surface free energy of polymers, J. Appl. Polym. Sci, vol.13, pp.1741-1747, 1969.

F. M. Fowkes, Attractive forces at interfaces, Ind. Eng. Chem, vol.56, pp.40-52, 1964.

S. K. Rhee, Surface energies of silicate glasses calculated from their wettability data, Journal of Materials Science, vol.12, pp.823-824, 1977.

J. H. Clint and A. C. Wicks, Adhesion under water: surface energy considerations, International Journal of Adhesion and Adhesives, vol.21, pp.267-273, 2001.

K. B. Lim and D. C. Lee, Surface modification of glass and glass fibres by plasma surface treatment, Surface and Interface Analysis, vol.36, pp.254-258, 2004.

J. J. Cras, C. A. Rowe-taitt, D. A. Nivens, and F. S. Ligler, Comparison of chemical cleaning methods of glass in preparation for silanization, Biosens. Bioelectron, vol.14, pp.683-688, 1999.

B. W. Yates and A. M. Duffy, Statistical Analysis of the Metrological Properties of Float Glass, Advances in X-Ray/Euv Optics and Components Iii, p.70770, 2008.

S. Wu, Calculation of interfacial tension in polymer systems, Journal of Polymer Science Part C: Polymer Symposia, vol.34, pp.19-30, 1971.

S. Wu, J. Bandrup, and E. H. Immergut, Polymer Handbook, pp.414-426, 1989.

S. Wu, J. Brandrup, E. H. Immergut, and E. A. Grulke, Polymer Handbook, pp.521-535, 1999.

S. Omenyi, A. Neumann, and C. Vanoss, Attraction and repulsion of solid particles by solidification fronts I. thermodynamic effects, J. Appl. Phys, vol.52, pp.789-795, 1981.

T. Matsunaga, Surface Free-Energy Analysis of Polymers and Its Relation to Surface Composition, J. Appl. Polym. Sci, vol.21, pp.2847-2854, 1977.

T. Fort and F. M. Fowkes, Contact Angle, Wettability and Adhesion, pp.302-316, 1964.

J. Dann, Forces involved in adhesive process I. critical surface tensions of polymeric solids as determined with polar liquids, J. Colloid Interface Sci, vol.32, p.302, 1970.

R. E. Smith, Surface Energy Data -Assorted Polymers, 2009.

G. Cazaux, Faisabilité des procédés LCM pour l'élaboration de composites renfort continu à matrice thermoplastique polyamide, 2016.

B. Ratner and S. Yoon, Polyurethane Surfaces: Solvent and Temperature Induced Structural Rearrangements, Polymer Surface Dynamics, pp.137-152, 1988.

J. Argyropoulos, B. Erdem, D. Bhattacharjee, and P. Foley, Natural oil polyols for waterborne polyurethane dispersions, JCT Coatings Tech, vol.6, pp.44-49, 2009.

B. Villatte, Overmoulding of a thermoplastic composite by a semi-crystalline polymer: characterization of the adhesion, 2015.

T. Zhang, Y. Zhao, H. Li, and B. Zhang, Effect of polyurethane sizing on carbon fibers surface and interfacial adhesion of fiber/polyamide 6 composites, J. Appl. Polym. Sci, vol.135, 2018.

X. Gao, J. W. Gillespie, R. E. Jensen, W. Li, B. Z. Haque et al., Effect of fiber surface texture on the mechanical properties of glass fiber reinforced epoxy composite, Composites Part A: Applied Science and Manufacturing, vol.74, pp.10-17, 2015.

J. L. Thomason, Glass Fibre Sizings: A review of the scientific literature, 2015.

J. L. Thomason and L. J. Adzima, Sizing up the interphase: an insider's guide to the science of sizing, Compos. Pt. A-Appl. Sci. Manuf, vol.32, pp.313-321, 2001.

F. R. Jones, A Review of Interphase Formation and Design in Fibre-Reinforced Composites, Journal of Adhesion Science and Technology, vol.24, pp.171-202, 2010.

H. N. Petersen, Investigation of sizing -from glass fibre surface to composite interface, 2017.

P. Zinck, E. Mader, and J. F. Gerard, Role of silane coupling agent and polymeric film former for tailoring glass fiber sizings from tensile strength measurements, J. Mater. Sci, vol.36, pp.5245-5252, 2001.

E. P. Plueddemann, Silane Coupling Agents, 1982.

M. J. Azzopardi and H. Arribart, In Situ FTIR Study of the Formation of an Organosilane Layer at the Silica/Solution Interface, The Journal of Adhesion, vol.46, pp.103-115, 1994.

C. P. Tripp and M. L. Hair, An infrared study of the reaction of octadecyltrichlorosilane with silica, Langmuir, vol.8, pp.1120-1126, 1992.

D. Wang and F. R. Jones, ToF-SIMS and XPS studies of the interaction of silanes and matrix resins with glass surfaces, Surf. Interface Anal, vol.20, pp.457-467, 1993.

R. Plonka, E. Mäder, S. L. Gao, C. Bellmann, V. Dutschk et al., Adhesion of epoxy/glass fibre composites influenced by aging effects on sizings, Composites Part A: Applied Science and Manufacturing, vol.35, pp.1207-1216, 2004.

H. Ishida and J. L. Koenig, An investigation of the coupling agent/matrix interface of fiberglass reinforced plastics by fourier transform infrared spectroscopy, J. Polym. Sci. Polym. Phys. Ed, vol.17, pp.615-626, 1979.

S. G. Turrión, D. Olmos, and J. González-benito, Complementary characterization by fluorescence and AFM of polyaminosiloxane glass fibers coatings, Polymer Testing, vol.24, pp.301-308, 2005.

I. V. Chapitre, Étude de l'influence d'agents de couplage, seuls et associés à cPA

G. Ozkoc, G. Bayram, and E. Bayramli, Effects of polyamide 6 incorporation to the short glass fiber reinforced ABS composites: an interfacial approach, Polymer, vol.45, pp.8957-8966, 2004.

S. J. Park and J. S. Jin, Effect of silane coupling agent on mechanical interfacial properties of glass fiber-reinforced unsaturated polyester composites, J. Polym. Sci. B Polym. Phys, vol.41, pp.55-62, 2003.

M. Zhu, M. Z. Lerum, and W. Chen, How To Prepare Reproducible, Homogeneous, and Hydrolytically Stable Aminosilane-Derived Layers on Silica, Langmuir, vol.28, pp.416-423, 2012.

G. S. Caravajal, D. E. Leyden, G. R. Quinting, and G. E. Maciel, Structural characterization of (3-aminopropyl)triethoxysilane-modified silicas by silicon-29 and carbon-13 nuclear magnetic resonance, Anal. Chem, vol.60, pp.1776-1786, 1988.

S. R. Culler, H. Ishida, and J. L. Koenig, The silane interphase of composites: Effects of process conditions on ?-aminopropyltriethoxysilane, Polym Compos, vol.7, pp.231-238, 1986.

G. M. Nishioka, Interaction of organosilanes with glass fibers, Journal of NonCrystalline Solids, vol.120, pp.102-107, 1990.

A. T. Dibenedetto and D. A. Scola, Characterization of S-Glass-Polymer Interfaces Using Ion Scattering Spectroscopy and Scattered Ion Mass-Spectroscopy, J. Colloid Interface Sci, vol.64, pp.480-500, 1978.

H. R. Brown, The Adhesion of Polymers: Relations Between Properties of Polymer Chains and Interface Toughness, The Journal of Adhesion, vol.82, pp.1013-1032, 2006.

J. L. Thomason, Interfacial strength in thermoplastic composites -at last an industry friendly measurement method?, Composites Part A: Applied Science and Manufacturing, vol.33, pp.1283-1288, 2002.

J. L. Thomason and L. Yang, Temperature dependence of the interfacial shear strength in glass-fibre epoxy composites, Compos. Sci. Technol, vol.96, pp.7-12, 2014.

F. R. Jones, Interphase formation and control in fibre composite materials, Interfacial Effects in Particulate, Fibrous and Layered Composite Materials, vol.116, pp.41-59, 1996.

X. M. Liu, J. L. Thomason, and F. R. Jones, XPS and AFM study of the structure of hydrolysed aminosilane on e-glass surfaces, 2009.

G. Jak?a, B. ?tefane, and J. Kova?, Influence of different solvents on the morphology of APTMS-modified silicon surfaces, Applied Surface Science, vol.315, pp.516-522, 2014.

R. Chepyala and S. Panda, Tunable surface free energies of functionalized molecular layers on Si surfaces for microfluidic immunosensor applications, Appl. Surf. Sci, vol.271, pp.77-85, 2013.

J. Canning, I. Petermann, and K. Cook, Surface treatment of silicate based glass: base Piranha treatment versus 193nm laser processing, Asia Pacific Optical Sensors Conference, 2012.
DOI : 10.1117/12.915823

I. V. Chapitre, Étude de l'influence d'agents de couplage, seuls et associés à cPA

E. Felder, Surfaces, tribologie et formage des matériaux: mélanges offerts à François Delamare pour son 60e anniversaire, Presses des MINES, 2001.

K. B. Lim and D. C. Lee, Surface modification of glass and glass fibres by plasma surface treatment, Surface and Interface Analysis, vol.36, pp.254-258, 2004.
DOI : 10.1002/sia.1682

D. K. Owens and R. C. Wendt, Estimation of the surface free energy of polymers, J. Appl. Polym. Sci, vol.13, pp.1741-1747, 1969.

S. Wu, Calculation of interfacial tension in polymer systems, Journal of Polymer Science Part C: Polymer Symposia, vol.34, pp.19-30, 1971.

S. Omenyi, A. Neumann, and C. Vanoss, Attraction and repulsion of solid particles by solidification fronts I. thermodynamic effects, J. Appl. Phys, vol.52, pp.789-795, 1981.

T. Matsunaga, Surface Free-Energy Analysis of Polymers and Its Relation to Surface Composition, J. Appl. Polym. Sci, vol.21, pp.2847-2854, 1977.
DOI : 10.1002/app.1977.070211020

T. Fort and F. M. Fowkes, Contact Angle, Wettability and Adhesion, pp.302-316, 1964.

J. Dann, Forces involved in adhesive process I. critical surface tensions of polymeric solids as determined with polar liquids, J. Colloid Interface Sci, vol.32, p.302, 1970.
DOI : 10.1016/0021-9797(70)90055-x

G. Cazaux, Faisabilité des procédés LCM pour l'élaboration de composites renfort continu à matrice thermoplastique polyamide, 2016.

C. M. Weikart and H. K. Yasuda, Modification, degradation, and stability of polymeric surfaces treated with reactive plasmas, Journal of Polymer Science Part A: Polymer Chemistry, vol.38, pp.3028-3042, 2000.

E. Smith and W. Chen, How To Prevent the Loss of Surface Functionality Derived from Aminosilanes, Langmuir, vol.24, pp.12405-12409, 2008.

P. Lennon, E. Espuche, H. Sautereau, and D. Sage, Influence of microwave plasma treatment on the wettability and the adhesive properties of polyamides films with an epoxy resin, Int. J. Adhes. Adhes, vol.19, pp.273-279, 1999.

Y. T. Liao, A study of glass fiber-epoxy composite interfaces, Polym Compos, vol.10, pp.424-428, 1989.

I. V. Chapitre, Étude de l'influence d'agents de couplage, seuls et associés à cPA Références

P. Gao, K. B. Su, Y. L. Ward, and L. T. Weng, Effects of chemical composition and thermal stability of finishes on the compatibility between glass fiber and high melting temperature thermoplastics, Polym. Compos, vol.21, pp.312-321, 2000.

R. E. Allred, S. P. Wesson, E. E. Shin, L. Inghram, L. Mccorkle et al., The influence of sizings on the durability of high-temperature polymer composites, High Perform. Polym, vol.15, pp.395-419, 2003.

D. J. Ireland, J. G. Nel, and R. G. Keske, Aqueous-based polyamide-amic acid compositions, pp.6479581-6479582, 2002.

C. Ozkan, N. Karsli, A. Aytac, and V. Deniz, Short carbon fiber reinforced polycarbonate composites: Effects of different sizing materials, Composites Part B: Engineering, vol.62, pp.230-235, 2014.

H. Yuan, S. Zhang, C. Lu, S. He, and F. An, Improved interfacial adhesion in carbon fiber/polyether sulfone composites through an organic solvent-free polyamic acid sizing, Applied Surface Science, vol.279, pp.279-284, 2013.
DOI : 10.1016/j.apsusc.2013.04.085

W. B. Liu, S. Zhang, L. F. Hao, W. C. Jiao, F. Yang et al., Properties of carbon fiber sized with poly(phthalazinone ether ketone) resin, Journal of Applied Polymer Science, vol.128, pp.3702-3709, 2012.
DOI : 10.1002/app.38605

I. Giraud, Élaboration d'ensimages thermoplastiques thermostables : influence sur le comportement mécanique des composites PEEK / fibres de carbone, 2011.

I. Giraud, S. Franceschi-messant, E. Perez, C. Lacabanne, and E. Dantras, Preparation of aqueous dispersion of thermoplastic sizing agent for carbon fiber by emulsion/solvent evaporation, Applied Surface Science, vol.266, pp.94-99, 2013.
URL : https://hal.archives-ouvertes.fr/hal-00835632

J. M. Bergerat, I. Giraud, E. Dantras, E. Perez, and C. Lacabanne, Novel stable aqueous dispersions of high performance thermoplastic polymer nanoparticles and their uses as film generating agents, 2011.

J. L. Thomason, Glass Fibre Sizings: A review of the scientific literature, 2015.

B. K. Chen, C. T. Su, M. C. Tseng, and S. Y. Tsay, Preparation of polyetherimide nanocomposites with improved thermal, mechanical and dielectric properties, Polym. Bull, vol.57, pp.671-681, 2006.

D. K. Owens and R. C. Wendt, Estimation of the surface free energy of polymers, J. Appl. Polym. Sci, vol.13, pp.1741-1747, 1969.

S. Wu, Calculation of interfacial tension in polymer systems, Journal of Polymer Science Part C: Polymer Symposia, vol.34, pp.19-30, 1971.

K. Asfardjani, Y. Segui, Y. Aurelle, and N. Abidine, Effect of Plasma Treatments on Wettability of Polysulfone and Polyetherimide, J. Appl. Polym. Sci, vol.43, pp.271-281, 1991.

M. Kaba, N. Raklaoui, M. Guimon, and A. Mas, Improvement of the water selectivity of ULTEM poly(ether imide) pervaporation films by an allylamine-plasma-polymerized layer, Journal of Applied Polymer Science, vol.97, pp.2088-2096, 2005.
URL : https://hal.archives-ouvertes.fr/hal-00383332

N. Bernet, P. E. Bourban, and J. A. Manson, On the characterization of wetting and adhesion in glass fiber-PA12 composites, J. Thermoplast. Compos. Mater, vol.13, pp.434-450, 2000.

J. Karger-kocsis, H. Mahmood, and A. Pegoretti, Recent advances in fiber/matrix interphase engineering for polymer composites, Progress in Materials Science, vol.73, pp.1-43, 2015.

J. Chen, X. Zhou, H. Ge, D. Wang, H. Liu et al., Preparation and Performance of Nano-SiO2 Stabilized Pickering Emulsion Type Sizing Agent for Glass Fiber, Polym. Compos, vol.37, pp.334-341, 2016.

J. Rausch, R. C. Zhuang, and E. Maeder, Application of nanomaterials in sizings for glass fibre/polypropylene hybrid yarn spinning, Materials Technology, vol.24, pp.29-35, 2009.

Y. Yang, C. X. Lu, X. L. Su, G. P. Wu, and X. K. Wang, Effect of nano-SiO2 modified emulsion sizing on the interfacial adhesion of carbon fibers reinforced composites, Mater. Lett, vol.61, pp.3601-3604, 2007.

, 2016 -Paints and varnishes -Pull-off test for adhesion, ISO, vol.4624, 2016.

B. Miller, P. Muri, L. Rebenfeld, and . Microbond, Method for Determination of the ShearStrength of a Fiber-Resin Interface, Compos. Sci. Technol, vol.28, pp.17-32, 1987.

Q. Wu, R. Zhao, Q. Liu, T. Jiao, J. Zhu et al., Simultaneous improvement of interfacial strength and toughness between carbon fiber and epoxy by introducing amino functionalized ZrO2 on fiber surface, Materials & Design, vol.149, pp.15-24, 2018.

W. Liu, S. Zhang, B. Li, F. Yang, W. Jiao et al., Improvement in interfacial shear strength and fracture toughness for carbon fiber reinforced epoxy composite by fiber sizing, Polymer Composites, vol.35, pp.482-488, 2014.

, NF ISO 15024 -Composites plastiques renforcés de fibres -Détermination de la ténacité à la rupture interlaminaire en mode I, GIC, de matériaux composites à matrice polymère renforcés de fibres unidirectionnelles, 2002.

, ISO 25217 Adhesives -Determination of the mode 1 adhesive fracture energy of structural adhesive joints using double cantilever beam and tapered double cantilever beam specimens, 2009.

V. Chapitre, Nouvelles voies d'amélioration de l'interface PA 6-6/verre et mise au point d'un test de DCB en mode I

, Par cette méthode, nous avons pu confirmer l'intérêt de l'utilisation d'agents de couplage, des agents filmogènes thermostables PEI et PAI, ainsi que de l'ajout de nanoparticules dans les ensimages. D'autre part, ces résultats nous ont permis, en comparaison avec ceux obtenus par le plot et la microgoutte, d'identifier la grandeur (force/ténacité) impactée par la modification des revêtements. Ici également, l'augmentation du nombre de mesures permettrait dans de futurs travaux de confirmer les tendances observées et d'étendre la méthode à l, complémentaires aux résultats d'adhésion obtenus par les tests du plot et de microgoutte

, L'observation de l'interpénétration entre les agents filmogènes et la matrice par différentes techniques (microscopie et spectroscopie par exemple) pourraient s'avérer intéressantes lors d'études ultérieures, de même que l'utilisation, comme agent filmogène, d'oligomères de polyamides de différentes longueurs de chaines