Engineering Copper Adhesion on Poly-Epoxy Surfaces Allows One-Pot Metallization of Polymer Composite Telecommunication Waveguides

Mass gain in the aerospace sector is highly demandable for energy savings and operational efficiency. Replacement of metal parts by polymer composites meets this prerequisite, provided the targeted functional properties are recovered. In the present contribution, we propose two innovative and scalab...

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Veröffentlicht in:	Coatings (Basel) 2021-01, Vol.11 (1), p.50
Hauptverfasser:	Addou, Fouzi, Duguet, Thomas, Ledru, Yohann, Mesnier, Didier, Vahlas, Constantin
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerospace industry Carbon fiber reinforced plastics Chemical Sciences Communication satellites Copper Fiber reinforced polymers Interfacial bonding Liquid injection Material chemistry Metallizing Metalorganic chemical vapor deposition Polymer matrix composites Polymers Pretreatment Radio frequency Thermal cycling Titanium alloys Waveguides
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creator	Addou, Fouzi Duguet, Thomas Ledru, Yohann Mesnier, Didier Vahlas, Constantin
description	Mass gain in the aerospace sector is highly demandable for energy savings and operational efficiency. Replacement of metal parts by polymer composites meets this prerequisite, provided the targeted functional properties are recovered. In the present contribution, we propose two innovative and scalable processes for the metallization of the internal faces of carbon fiber reinforced polymer radiofrequency waveguides foreseen for implementation in telecommunications satellites. They involve sequential direct liquid injection metalorganic chemical vapor deposition of copper and cobalt. The use of ozone pretreatment of the polymer surface prior deposition, or of cost effective anhydrous dimethoxyethane as solvent for the injection of the copper precursor, yield strongly adherent, 5 µm Cu films on the polymer composite. Their electrical resistivity is in the 4.1–5.0 μΩ·cm range, and they sustain thermal cycling between −175 °C and +170 °C. Such homogeneous and conformal films can be obtained at temperatures as low as 115 °C. Demonstration is achieved on a polymer composite waveguide, composed of metallized 60-mm long straight sections and of E-plane and H-plane elbows, that paves the way towards the metallization of scale one devices.
doi_str_mv	10.3390/coatings11010050
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subjects	Aerospace industry Carbon fiber reinforced plastics Chemical Sciences Communication satellites Copper Fiber reinforced polymers Interfacial bonding Liquid injection Material chemistry Metallizing Metalorganic chemical vapor deposition Polymer matrix composites Polymers Pretreatment Radio frequency Thermal cycling Titanium alloys Waveguides
title	Engineering Copper Adhesion on Poly-Epoxy Surfaces Allows One-Pot Metallization of Polymer Composite Telecommunication Waveguides
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