Electrochemical characterization of Al–Li alloys AA2099 and AA2055 for aeronautical applications: effect of thermomechanical treatments

Third-generation Al–Li alloys are high-performance materials that are very attractive for aircraft and aerospace applications due to their relatively low density, high specific strength, and stiffness. To study the effect of heat treatments on the electrochemical behavior of two high-performance alu...

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Veröffentlicht in:	Journal of solid state electrochemistry 2023-11, Vol.27 (11), p.3101-3117
Hauptverfasser:	Cerezo, H. Rivera, Tiburcio, C. Gaona, Miramontes, J. A. Cabral, Bautista-Margulis, Raúl Germán, Mendoza, D. Nieves, Bandala, E. Maldonado, Estupiñán-López, F. H., Calderón, F. Almeraya
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Sprache:	eng
Schlagworte:	Aging (artificial) Aluminum-lithium alloys Analytical Chemistry Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Condensed Matter Physics Corrosion Deformation Electrochemical analysis Electrochemical noise Electrochemistry Electrolytes Energy Storage Heat treating Heat treatment Kurtosis Original Paper Physical Chemistry Power spectral density Precipitates Quenching Solid solutions Thermomechanical treatment
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creator	Cerezo, H. Rivera Tiburcio, C. Gaona Miramontes, J. A. Cabral Bautista-Margulis, Raúl Germán Mendoza, D. Nieves Bandala, E. Maldonado Estupiñán-López, F. H. Calderón, F. Almeraya
description	Third-generation Al–Li alloys are high-performance materials that are very attractive for aircraft and aerospace applications due to their relatively low density, high specific strength, and stiffness. To study the effect of heat treatments on the electrochemical behavior of two high-performance aluminum-lithium alloys, in this work the electrochemical noise technique was used to evaluate the corrosion behavior of AA2099 and AA2055 alloys under three conditions of different heat treatments, an annealing treatment (T0), a second treatment in solid solution, followed by rapid cooling (quenching) and subsequent artificial aging (T6), and a third treatment in solid solution, tempering, cold deformation, and maturation artificial (T8). The time series obtained from the electrochemical noise tests were visually analyzed, as well as the statistical parameters such as localization index (LI), bias, and kurtosis. Analysis in the frequency domain was also performed by means of power spectral density (PSD) signals. In general, it was observed that the distribution of precipitates on the surface of the alloys considerably affects the corrosion performance, as well as the concentration of Cl-1 ions in the test electrolytes.
doi_str_mv	10.1007/s10008-023-05592-w
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To study the effect of heat treatments on the electrochemical behavior of two high-performance aluminum-lithium alloys, in this work the electrochemical noise technique was used to evaluate the corrosion behavior of AA2099 and AA2055 alloys under three conditions of different heat treatments, an annealing treatment (T0), a second treatment in solid solution, followed by rapid cooling (quenching) and subsequent artificial aging (T6), and a third treatment in solid solution, tempering, cold deformation, and maturation artificial (T8). The time series obtained from the electrochemical noise tests were visually analyzed, as well as the statistical parameters such as localization index (LI), bias, and kurtosis. Analysis in the frequency domain was also performed by means of power spectral density (PSD) signals. 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subjects	Aging (artificial) Aluminum-lithium alloys Analytical Chemistry Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Condensed Matter Physics Corrosion Deformation Electrochemical analysis Electrochemical noise Electrochemistry Electrolytes Energy Storage Heat treating Heat treatment Kurtosis Original Paper Physical Chemistry Power spectral density Precipitates Quenching Solid solutions Thermomechanical treatment
title	Electrochemical characterization of Al–Li alloys AA2099 and AA2055 for aeronautical applications: effect of thermomechanical treatments
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