Microstructure and corrosion behavior of AISI 316L duplex treated by means of ion nitriding and plasma based ion implantation and deposition

Austenitic stainless steels are the preferred materials for mechanical components in the food, oil and chemical industries due to their good corrosion resistance but they often suffer severe wear due to their poor tribological properties. Plasma surface engineering has been extended to stainless ste...

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Autores principales: Escalada, L., Lutz, J., Brühl, S.P., Fazio, M., Márquez, A., Mändl, S., Manova, D., Simison, S.N.
Formato: JOUR
Materias:
Corrosion resistance
Plasma ion implantation
Plasma nitriding
TiN coating
Cyclic potentiodynamic polarization
Localized corrosion resistances
Plasma based ion implantation and deposition
Plasma immersion ion implantation
Tribological properties
Austenitic stainless steel
Chemical industry
Corrosive effects
Deposition
Hard coatings
Ion implantation
Ions
Microstructure
Nitriding
Oils and fats
Plasma deposition
Plasmas
Titanium nitride
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_02578972_v223_n_p41_Escalada
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_02578972_v223_n_p41_Escalada
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spelling todo:paper_02578972_v223_n_p41_Escalada2023-10-03T15:11:41Z Microstructure and corrosion behavior of AISI 316L duplex treated by means of ion nitriding and plasma based ion implantation and deposition Escalada, L. Lutz, J. Brühl, S.P. Fazio, M. Márquez, A. Mändl, S. Manova, D. Simison, S.N. Corrosion resistance Plasma ion implantation Plasma nitriding TiN coating Cyclic potentiodynamic polarization Localized corrosion resistances Plasma based ion implantation and deposition Plasma immersion ion implantation Plasma ion implantation Plasma nitriding TiN coating Tribological properties Austenitic stainless steel Chemical industry Corrosive effects Deposition Hard coatings Ion implantation Ions Microstructure Nitriding Oils and fats Plasma deposition Plasmas Titanium nitride Corrosion resistance Austenitic stainless steels are the preferred materials for mechanical components in the food, oil and chemical industries due to their good corrosion resistance but they often suffer severe wear due to their poor tribological properties. Plasma surface engineering has been extended to stainless steel hardening, through the modification of the surface with ion nitriding or the application of hard coatings. In this work, AISI 316L samples were coated with titanium nitride by means of a cathodic arc (CA) and this technique was combined with plasma immersion ion implantation, in a process called plasma based ion implantation and deposition (PBII&D). The effect on corrosion resistance was analyzed, also considering ion nitriding as a pre-treatment. Microstructure and composition were analyzed by means of glancing angle XRD, SIMS, SEM, SEM-FIB and EDS. Localized corrosion resistance was analyzed in a cyclic potentiodynamic polarization experiment in 3.5% NaCl solution, and the corroded surface was analyzed with AFM, SEM and EDS as well. It was found that nitriding at 400 °C produces a thin nitrided layer with good corrosion resistance. A duplex TiN coating resulted in a further improvement of the corrosion resistance. Comparing cathodic arc and PBII&D coating techniques, the last one gives the thickest film and also the best corrosion behavior with good adhesion. © 2013 Elsevier B.V. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_02578972_v223_n_p41_Escalada
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Corrosion resistance
Plasma ion implantation
Plasma nitriding
TiN coating
Cyclic potentiodynamic polarization
Localized corrosion resistances
Plasma based ion implantation and deposition
Plasma immersion ion implantation
Plasma ion implantation
Plasma nitriding
TiN coating
Tribological properties
Austenitic stainless steel
Chemical industry
Corrosive effects
Deposition
Hard coatings
Ion implantation
Ions
Microstructure
Nitriding
Oils and fats
Plasma deposition
Plasmas
Titanium nitride
Corrosion resistance
spellingShingle Corrosion resistance
Plasma ion implantation
Plasma nitriding
TiN coating
Cyclic potentiodynamic polarization
Localized corrosion resistances
Plasma based ion implantation and deposition
Plasma immersion ion implantation
Plasma ion implantation
Plasma nitriding
TiN coating
Tribological properties
Austenitic stainless steel
Chemical industry
Corrosive effects
Deposition
Hard coatings
Ion implantation
Ions
Microstructure
Nitriding
Oils and fats
Plasma deposition
Plasmas
Titanium nitride
Corrosion resistance
Escalada, L.
Lutz, J.
Brühl, S.P.
Fazio, M.
Márquez, A.
Mändl, S.
Manova, D.
Simison, S.N.
Microstructure and corrosion behavior of AISI 316L duplex treated by means of ion nitriding and plasma based ion implantation and deposition
topic_facet Corrosion resistance
Plasma ion implantation
Plasma nitriding
TiN coating
Cyclic potentiodynamic polarization
Localized corrosion resistances
Plasma based ion implantation and deposition
Plasma immersion ion implantation
Plasma ion implantation
Plasma nitriding
TiN coating
Tribological properties
Austenitic stainless steel
Chemical industry
Corrosive effects
Deposition
Hard coatings
Ion implantation
Ions
Microstructure
Nitriding
Oils and fats
Plasma deposition
Plasmas
Titanium nitride
Corrosion resistance
description Austenitic stainless steels are the preferred materials for mechanical components in the food, oil and chemical industries due to their good corrosion resistance but they often suffer severe wear due to their poor tribological properties. Plasma surface engineering has been extended to stainless steel hardening, through the modification of the surface with ion nitriding or the application of hard coatings. In this work, AISI 316L samples were coated with titanium nitride by means of a cathodic arc (CA) and this technique was combined with plasma immersion ion implantation, in a process called plasma based ion implantation and deposition (PBII&D). The effect on corrosion resistance was analyzed, also considering ion nitriding as a pre-treatment. Microstructure and composition were analyzed by means of glancing angle XRD, SIMS, SEM, SEM-FIB and EDS. Localized corrosion resistance was analyzed in a cyclic potentiodynamic polarization experiment in 3.5% NaCl solution, and the corroded surface was analyzed with AFM, SEM and EDS as well. It was found that nitriding at 400 °C produces a thin nitrided layer with good corrosion resistance. A duplex TiN coating resulted in a further improvement of the corrosion resistance. Comparing cathodic arc and PBII&D coating techniques, the last one gives the thickest film and also the best corrosion behavior with good adhesion. © 2013 Elsevier B.V.
format JOUR
author Escalada, L.
Lutz, J.
Brühl, S.P.
Fazio, M.
Márquez, A.
Mändl, S.
Manova, D.
Simison, S.N.
author_facet Escalada, L.
Lutz, J.
Brühl, S.P.
Fazio, M.
Márquez, A.
Mändl, S.
Manova, D.
Simison, S.N.
author_sort Escalada, L.
title Microstructure and corrosion behavior of AISI 316L duplex treated by means of ion nitriding and plasma based ion implantation and deposition
title_short Microstructure and corrosion behavior of AISI 316L duplex treated by means of ion nitriding and plasma based ion implantation and deposition
title_full Microstructure and corrosion behavior of AISI 316L duplex treated by means of ion nitriding and plasma based ion implantation and deposition
title_fullStr Microstructure and corrosion behavior of AISI 316L duplex treated by means of ion nitriding and plasma based ion implantation and deposition
title_full_unstemmed Microstructure and corrosion behavior of AISI 316L duplex treated by means of ion nitriding and plasma based ion implantation and deposition
title_sort microstructure and corrosion behavior of aisi 316l duplex treated by means of ion nitriding and plasma based ion implantation and deposition
url http://hdl.handle.net/20.500.12110/paper_02578972_v223_n_p41_Escalada
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