Investigation into the stress corrosion cracking properties of AA2099, an Al-Li-Cu alloy

Investigation into the stress corrosion cracking properties of AA2099, an Al-Li-Cu alloy

Bibliographic Details
Main Author: Padgett, Barbara Nicole
Language:English
Published: The Ohio State University / OhioLINK 2008
Subjects:
Materials Science
aluminum-lithium-copper alloys
stress corrosion cracking
friction stir welding
anodic dissolution
2099
Online Access:http://rave.ohiolink.edu/etdc/view?acc_num=osu1204515486
id ndltd-OhioLink-oai-etd.ohiolink.edu-osu1204515486
record_format oai_dc
spelling ndltd-OhioLink-oai-etd.ohiolink.edu-osu12045154862021-08-03T05:53:19Z Investigation into the stress corrosion cracking properties of AA2099, an Al-Li-Cu alloy Padgett, Barbara Nicole Materials Science aluminum-lithium-copper alloys stress corrosion cracking friction stir welding anodic dissolution 2099 <p>Recently developed Al-Li-Cu alloys show great potential for implementation in the aerospace industry because of the attractive mix of good mechanical properties and low density. AA2099 is an Al-Li-Cu alloy with the following composition Al-2.69wt%Cu-1.8wt%Li-0.6wt%Zn-0.3wt%Mg-0.3wt%Mn-0.08wt%Zr. The environmental assisted cracking and localized corrosion behavior of the AA2099 was investigated in this thesis.</p> <p>The consequences of uncontrolled grain boundary precipitation via friction stir welding on the stress corrosion cracking (SCC) behavior of AA2099 were investigated first. Using constant extension rate testing, intergranular corrosion immersion experiments, and potentiodynamic scans, the heat-affected zone on the trailing edge of the weld (HTS) was determined to be most susceptible of the weld zones. The observed SCC behavior for the HTS was linked to the dissolution of an active phase (Al<sub>2</sub>CuLi, T<sub>1</sub>) populating the grain boundary. It should be stated that the SCC properties of AA2099 in the as-received condition were determined to be good. </p><p>Focus was then given to the electrochemical behavior of precipitate phases that may occupy grain and sub-grain boundaries in AA2099. The grain boundary microchemistry and micro-electrochemistry have been alluded to within the literature as having significant influence on the SCC behavior of Al-Li-Cu alloys. Major precipitates found in this alloy system are T<sub>1</sub> (Al<sub>2</sub>CuLi), T<sub>2 </sub>(Al<sub>7.5</sub>Cu<sub>4</sub>Li), T<sub>B</sub> (Al<sub>6</sub>CuLi<sub>3</sub>), and θ (Al<sub>2</sub>Cu). These phases were produced in bulk form so that the electrochemical nature of each phase could be characterized. It was determined T<sub>1</sub> was most active electrochemically and θ was least. When present on grain boundaries in the alloy, electrochemical behavior of the individual precipitates aligned with the observed corrosion behavior of the alloy (e.g. T<sub>B</sub> was accompanied by general pitting corrosion and T<sub>1</sub> was accompanied by intergranular corrosion attack). In addition to the electrochemical behavior of the above-mentioned intermetallics, the phenomenon of Zn substituting for Cu in T<sub>1</sub> was also studied. It was determined that for Zn substitutions up to 8.4wt%, improved corrosion behavior of T<sub>1</sub> would occur by dealloying of Zn and Li.</p> <p>Lastly, isothermal aging treatments at 160°C and 190°C were conducted to vary the grain boundary structures in a systematic way. The SCC behaviors for the under-aged, peak-aged, and over-aged condition were studied using CERT and alternate immersion testing at each temperature. The severely under-aged condition (≤ 9 hours) at 160°C proved to have poorest SCC resistance. The over-aged condition at 160°C (≥ 24 hours) also had degraded SCC resistance. In contrast the 190°C isothermal aging condition produced better SCC resistance than 160°C isothermal aging temperature for all conditions. The differences in behavior were linked to the species populating the grain boundaries in each isothermal aging condition (T<sub>2</sub> at 190°C and T<sub>1</sub> at 160°C). </p> 2008-03-18 English text The Ohio State University / OhioLINK http://rave.ohiolink.edu/etdc/view?acc_num=osu1204515486 http://rave.ohiolink.edu/etdc/view?acc_num=osu1204515486 unrestricted This thesis or dissertation is protected by copyright: all rights reserved. It may not be copied or redistributed beyond the terms of applicable copyright laws.
collection NDLTD
language English
sources NDLTD
topic Materials Science
aluminum-lithium-copper alloys
stress corrosion cracking
friction stir welding
anodic dissolution
2099
spellingShingle Materials Science
aluminum-lithium-copper alloys
stress corrosion cracking
friction stir welding
anodic dissolution
2099
Padgett, Barbara Nicole
Investigation into the stress corrosion cracking properties of AA2099, an Al-Li-Cu alloy
author Padgett, Barbara Nicole
author_facet Padgett, Barbara Nicole
author_sort Padgett, Barbara Nicole
title Investigation into the stress corrosion cracking properties of AA2099, an Al-Li-Cu alloy
title_short Investigation into the stress corrosion cracking properties of AA2099, an Al-Li-Cu alloy
title_full Investigation into the stress corrosion cracking properties of AA2099, an Al-Li-Cu alloy
title_fullStr Investigation into the stress corrosion cracking properties of AA2099, an Al-Li-Cu alloy
title_full_unstemmed Investigation into the stress corrosion cracking properties of AA2099, an Al-Li-Cu alloy
title_sort investigation into the stress corrosion cracking properties of aa2099, an al-li-cu alloy
publisher The Ohio State University / OhioLINK
publishDate 2008
url http://rave.ohiolink.edu/etdc/view?acc_num=osu1204515486
work_keys_str_mv AT padgettbarbaranicole investigationintothestresscorrosioncrackingpropertiesofaa2099anallicualloy
_version_ 1719427208491040768

Similar Items