5xxx series Al alloys are non-heat treatable, moderate strength wrought alloys with 3-5% Mg. These alloys are widely used for marine, automotive, and military applications due to their high strength-to-weight ratio, mechanical properties, and corrosion resistance [1]. However, at moderate and high temperatures (50-250°C) these alloys are vulnerable to sensitization, which is precipitation of β phase (Al3Mg2) preferentially at grain boundaries (GBs) [2]. This β phase is more electrochemically active compared to the rest of the Al matrix [3]. As a result, the β phase is preferentially dissolved when the alloys are exposed to corrosive environments such as salt water, making them susceptible to intergranular corrosion (IGC) and stress corrosion cracking (SCC) [3–5]. Multiple reports have correlated high degrees of sensitization values with increased corrosion fatigue crack growth rates [30] and the intergranular β phase coverage to intergranular stress corrosion cracking (IGSCC) susceptibility in Al-Mg alloys [3–5, 21, 33], motivating the search for sensitization-resistant Al alloys.
Studies on β phase formation have shown that super saturated solid solution of Mg is the starting point, from which GP zones (Guinier Preston Zones, also known as δ”) consisting of Mg rich clusters form. These are observed at relatively low temperatures up to the critical temperature range of 45-50°C [8, 9]. Once the critical temperature is reached, these clusters transform to β’’ spherical particles with a composition of Al3Mg [7, 10]. The GP zones and β’’ particles dissolve and β’ precipitates and vacancy voids/dislocation loops form at grain boundaries during annealing. This formation begins at 100°C and accelerates at 150°C [6]. At temperatures above 200°C, the stable equilibrium β phase forms from β’ and above 250°C β phase forms from the direct decomposition of Al matrix super saturated solid solution [2, 8, 9]. A recent study reported the existence of stable β at higher temperatures (325oC) [34]. The precipitate formation was observed mainly at the grain boundaries and defects in the material [11, 6]. However, there exists a lack of information on which microstructural features influence the β precipitation during sensitization.
Several studies have been conducted to understand the influence of grain boundary character, especially the misorientation angle, on β precipitation. Work by Davenport et al. on sensitized AA5182 alloy reported that low angle grain boundaries are immune to sensitization as determined by a H3PO4 etch [12]. Similarly, work by Kaigorodova suggested that β phase growth is more favorable on high angle grain boundaries compared to low angle grain boundaries [13]. While most studies suggest that low angle boundaries are immune to precipitation [12–14], Scotto D’Antuono et al. [15] showed that precipitation exists at grain boundaries with low angle misorientation. Accelerated in situ transmission electron microscopy (TEM) heating experiments conducted on AA5456 H116 alloy revealed β precipitates on both on low and high angle grain boundaries. A recent study by Zhang et al. comparing the continuity of β phase on high angle and low angle grain boundaries found that high angle grain boundaries have higher continuity in precipitation, making them more vulnerable to IGC [16]. These studies suggest that additional factors beyond misorientation angle may play a role in susceptibility to β phase formation.
Beyond grain boundary characteristics, there have been a few studies on the effect of dislocation density on β precipitation [17, 18, 19–21, 32]. Scotto D’Antuono et al. investigated the formation and growth of β precipitates in AA5456 using in situ TEM annealing experiments at 300°C. An increase in growth rate of the precipitates was reported due to pipe diffusion through dislocations near the grain boundaries [17]. This study also reported favorable heterogeneous nucleation of precipitates at Mn-rich particles. A similar effect was observed in a nanocrystalline Al-7.5% Mg synthesized by cryomilling and hot pressing. Grain boundaries enriched with Mg were observed under high resolution TEM, which was attributed to the high concentration of dislocations closer to grain boundaries providing diffusion channels and accelerating the sensitization [18, 19]. Gronksy and Furrer reported that the presence of dislocations would dominate the precipitation reaction under certain conditions [21]. These studies have in general relied on a relatively small number of grain boundaries, with questions remaining about the statistical importance of dislocation density on sensitization susceptibility. A study performed by Tan and Allen [20] used a thermomechanical treatment to enhance the corrosion resistance of AA5083 alloy and found that increases in the global dislocation density and low angle grain boundaries lead to better corrosion resistance. However, this study did not investigate the influence of the local microstructure state on IGC susceptibility.
In the current study, the combined influence of dislocation density and grain boundary misorientation angle on β precipitation was investigated using a correlative optical microscopy/electron backscatter diffraction (EBSD)-based approach. Previous work has shown that it is possible to quantify correlative relationship using EBSD to understand the effects of grain boundaries and secondary phase particles on dislocation accumulation [37]. The current study uses a similar correlative microscopy approach to rapidly characterize hundreds of grain boundaries in terms of their misorientation angle, surrounding defect distribution, and prevalence of β phase precipitates and to establish quantitative correlations between them.