<?xml version="1.0" encoding="UTF-8"?><!DOCTYPE article  PUBLIC "-//NLM//DTD Journal Publishing DTD v3.0 20080202//EN" "http://dtd.nlm.nih.gov/publishing/3.0/journalpublishing3.dtd"><article xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink" dtd-version="3.0" xml:lang="en" article-type="research article"><front><journal-meta><journal-id journal-id-type="publisher-id">MSA</journal-id><journal-title-group><journal-title>Materials Sciences and Applications</journal-title></journal-title-group><issn pub-type="epub">2153-117X</issn><publisher><publisher-name>Scientific Research Publishing</publisher-name></publisher></journal-meta><article-meta><article-id pub-id-type="doi">10.4236/msa.2019.102011</article-id><article-id pub-id-type="publisher-id">MSA-90293</article-id><article-categories><subj-group subj-group-type="heading"><subject>Articles</subject></subj-group><subj-group subj-group-type="Discipline-v2"><subject>Chemistry&amp;Materials Science</subject></subj-group></article-categories><title-group><article-title>
 
 
  Microstructure and Quasi-Static Mechanical Behavior of Cryoforged AA2519 Alloy
 
</article-title></title-group><contrib-group><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Amin</surname><given-names>Azimi</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref><xref ref-type="corresp" rid="cor1"><sup>*</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Gbadebo</surname><given-names>Moses Owolabi</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Hamid</surname><given-names>Fallahdoost</given-names></name><xref ref-type="aff" rid="aff2"><sup>2</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Nikhil</surname><given-names>Kumar</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Horace</surname><given-names>Whitworth</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref></contrib></contrib-group><aff id="aff1"><addr-line>Department of Mechanical Engineering, Howard University, Washington DC, USA</addr-line></aff><aff id="aff2"><addr-line>Department of Mechanical Engineering, Materials Science and Engineering Program, Binghamton University (SUNY), Binghamton, NY, USA</addr-line></aff><pub-date pub-type="epub"><day>28</day><month>01</month><year>2019</year></pub-date><volume>10</volume><issue>02</issue><fpage>137</fpage><lpage>149</lpage><history><date date-type="received"><day>9,</day>	<month>January</month>	<year>2019</year></date><date date-type="rev-recd"><day>27,</day>	<month>January</month>	<year>2019</year>	</date><date date-type="accepted"><day>30,</day>	<month>January</month>	<year>2019</year></date></history><permissions><copyright-statement>&#169; Copyright  2014 by authors and Scientific Research Publishing Inc. </copyright-statement><copyright-year>2014</copyright-year><license><license-p>This work is licensed under the Creative Commons Attribution International License (CC BY). http://creativecommons.org/licenses/by/4.0/</license-p></license></permissions><abstract><p>
 
 
  In this study, AA2519 alloy was initially processed by multi axial forging (MAF) at room and cryogenic temperatures. Subsequently, the microstructure and the mechanical behavior of the processed samples under quasi-static loading were investigated to determine the influence of cryogenic forging on alloys’ subgrains dimensions, grain boundaries interactions, strength, ductility and toughness. In addition, the failure mechanisms at the tensile rupture surfaces were characterized using scanning electron micro-scope (SEM). The results show significant improvements in the strength, ductility and toughness of the alloy as a result of the cryogenic MAF process. The formation of nanoscale crystallite microstructure, heavily deformed grains with high density of grain boundaries and second phase breakage to finer particles were characterized as the main reasons for the increase in the mechanical properties of the cryogenic forged samples. The cryogenic processing of the alloy resulted in the formation of an ultrafine grained material with tensile strength and toughness that are ~41% and ~80% higher respectively after 2 cycles MAF when compared with the materials processed at ambient temperature. The fractography analysis on the tested materials shows a substantial ductility improvement in the cryoforged (CF) samples when compared to the room temperature forged (RTF) samples which is in alignment with their stress-strain profiles. However, extended forging at higher cycles than 2 cycles led only to increase in strength at the expense of ductility for both the CF and RTF samples.
 
</p></abstract><kwd-group><kwd>AA2519 Aluminum Alloy</kwd><kwd> Cryogenic Forging</kwd><kwd> Quasi-Static Mechanical Behavior</kwd><kwd> Microstructure Investigation</kwd><kwd> Fractography Analysis</kwd></kwd-group></article-meta></front><body><sec id="s1"><title>1. Introduction</title><p>Severe Plastic Deformation (SPD) may be described as a metal forming process in which an ultra-large plastic strain is applied into a bulk metal leading to a gradual formation of nano/ultrafine grained structures [<xref ref-type="bibr" rid="scirp.90293-ref1">1</xref>] . SPD has emerged as a promising method for the development of bulk ultrafine grained (UFG) and nanostructured materials over the last two decades [<xref ref-type="bibr" rid="scirp.90293-ref2">2</xref>] . Accumulation of dislocations in cell walls followed by formation of small and large angle grain boundaries within the original cell satisfies the required conditions for the grain size refinement during SPD process [<xref ref-type="bibr" rid="scirp.90293-ref3">3</xref>] . Low-angle grain boundaries are formed in regions of high dislocation densities and then transformed into high-angle grain boundaries in high accumulated dislocation areas by extending the process. This results in a reduction of the grain size via the SPD process [<xref ref-type="bibr" rid="scirp.90293-ref4">4</xref>] . Several SPD methods such as Equal Channel Angular Pressing (ECAP) [<xref ref-type="bibr" rid="scirp.90293-ref5">5</xref>], Accumulative Roll-Bonding (ARB) [<xref ref-type="bibr" rid="scirp.90293-ref6">6</xref>], High Pressure Torsion (HPT) [<xref ref-type="bibr" rid="scirp.90293-ref7">7</xref>] and Multi Axial Forging (MAF) [<xref ref-type="bibr" rid="scirp.90293-ref8">8</xref>] have been developed. MAF is a relatively simple SPD process that consists of repeated compression in three orthogonal directions associated with a change in the axis to 90˚ in every pass leading to the attainment of a uniform texture with low aspect ratio grains within the material. Not only does it have the potential for scaling up of the processed products, but it also preserves the original shape with least distortion even after several cycles, which is ideal for industrial applications [<xref ref-type="bibr" rid="scirp.90293-ref9">9</xref>] .</p><p>Despite of the positive SPD impacts on microstructural modifications, the rate of defect storage and structural refinement decreases significantly with increasing strain due to dynamic recovery and recrystallization of grains during the plastic deformation [<xref ref-type="bibr" rid="scirp.90293-ref10">10</xref>] . In this regard, cryogenic SPD has been established as a much more effective approach while dynamic recovery is suppressed at a liquid nitrogen temperature and accordingly facilitates the formation of UFG structures. The complete suppression of dynamic recovery and recrystallization during the cryogenic plastic deformation preserves high density dislocations and other defects developed during the deformation, thus requiring less plastic deformation for generating UFG structure [<xref ref-type="bibr" rid="scirp.90293-ref11">11</xref>] [<xref ref-type="bibr" rid="scirp.90293-ref12">12</xref>] .</p><p>UFG materials are structurally identified by a large volume fraction of grain boundaries, which significantly affect their physical and mechanical characteristics such that mechanical strength of metals can be substantially improved by this grain size refinement into the sub-micrometer range [<xref ref-type="bibr" rid="scirp.90293-ref13">13</xref>] [<xref ref-type="bibr" rid="scirp.90293-ref14">14</xref>] . Particularly, UFG aluminum alloys are seeing as a lightweight substitute to the conventional heavy materials used in the automotive and the aerospace industries [<xref ref-type="bibr" rid="scirp.90293-ref15">15</xref>] . The small grain size with high fraction of atoms ascribed to the grain boundaries results in the increase in the mechanical strength of the materials without losing the toughness, which distinguishes this method from other strengthening methods such as heat treatment [<xref ref-type="bibr" rid="scirp.90293-ref16">16</xref>] . This distinction between UFG and coarse-grained polycrystalline materials has been very well explained by the Hall-Petch relationship and corresponds to different deformation mechanisms [<xref ref-type="bibr" rid="scirp.90293-ref17">17</xref>] . For instance, predominant mechanisms of plastic deformation for coarse grained metallic materials are intragrain dislocation slip and twinning. On the other hand, since activation energy of plastic deformation is close to the activation energy of grain boundary diffusion, the diffusion-controlled mechanisms such as grain boundary sliding and grain rotation can be efficiently activated in UFG materials due to large volume fraction of grain boundaries which are in a nonequilibrium state [<xref ref-type="bibr" rid="scirp.90293-ref18">18</xref>] . Some cryogenic SPD processes on various metals were studied by recent researches [<xref ref-type="bibr" rid="scirp.90293-ref12">12</xref>] [<xref ref-type="bibr" rid="scirp.90293-ref19">19</xref>] [<xref ref-type="bibr" rid="scirp.90293-ref20">20</xref>] [<xref ref-type="bibr" rid="scirp.90293-ref21">21</xref>] showing a considerable mechanical improvement.</p><p>To the best of the authors’ knowledge, no data is available in literature on the quasi-static mechanical behavior of the UFG AA2519 processed by MAF at cryogenic temperature. Thus, the main objective of this paper is to investigate the microstructure and mechanical properties of the cryoforged (CF) AA2519 using the room temperature forged (RTF) alloy as the reference material. In addition, the microstructure of the fractured surface was characterized to provide an insight into the failure mechanisms in the tested materials. The number of forging cycles is also considered as a variable to determine the effect of further processing cycle on the materials properties.</p></sec><sec id="s2"><title>2. Materials and Methods</title><p>A commercial AA2519 alloy was used in this study with the chemical compositions summarized in <xref ref-type="table" rid="table1">Table 1</xref>. The samples were first solution treated at a temperature 500˚C for 10 hrs in a controlled atmosphere of argon, and then quenched in water at ambient temperature. The MAF process was carried out in friction screw forging machine at a strain rate of 10 s<sup>−1</sup>. Axial compression at an equivalent true strain of (Δε) = ln(1/1.18) = −0.165 was successively induced for one forging pass. Thus, the cumulative strain in one cycle was calculated as (ΣΔε<sub>n</sub><sub>=1</sub>) = |Δε<sub>1</sub> + Δε<sub>2</sub> + Δε<sub>3</sub>| = −0.495. The extrusion direction of the starting sample was used as the first forging axis. To reach the cryogenic temperature, the samples were submerged in liquid nitrogen for 15 mins. The samples were then repeatedly forged by changing the axis through 90˚ in order to maintain the dimensional ratio of 1.18:1.11:1.0 at the end of the process. Prior to each pass, quenching in liquid nitrogen for about 5 to 10 min was conducted to keep the samples in a thermal equilibrium with the liquid nitrogen. Eventually, The AA2519 samples were subjected to cumulative strains of −0.99, −1.98 and −2.97 for 2 cycles (6 passes), 4 cycles (12 passes) and 6 cycles (18 passes), respectively. The structural changes of the alloys caused by cryogenic forging was evaluated by means of X-ray diffraction measurement (XRD) using a Philips diffractometer at a voltage and electrical current of 40 kV with Cu-Kα radiation (λ = 0.15406 nm).</p><table-wrap id="table1" ><label><xref ref-type="table" rid="table1">Table 1</xref></label><caption><title> Chemical composition of the AA2519 aluminum alloy</title></caption><table><tbody><thead><tr><th align="center" valign="middle" >Elements</th><th align="center" valign="middle" >Cu</th><th align="center" valign="middle" >Fe</th><th align="center" valign="middle" >Mg</th><th align="center" valign="middle" >Mn</th><th align="center" valign="middle" >Si</th><th align="center" valign="middle" >Ti</th><th align="center" valign="middle" >V</th><th align="center" valign="middle" >Zn</th><th align="center" valign="middle" >Zr</th><th align="center" valign="middle" >Al</th></tr></thead><tr><td align="center" valign="middle" >wt%</td><td align="center" valign="middle" >5.3 - 6.4</td><td align="center" valign="middle" >0.3</td><td align="center" valign="middle" >0.05 - 0.4</td><td align="center" valign="middle" >0.1 - 0.5</td><td align="center" valign="middle" >0.25</td><td align="center" valign="middle" >0.02 - 0.1</td><td align="center" valign="middle" >0.05 - 0.15</td><td align="center" valign="middle" >0.1</td><td align="center" valign="middle" >0.1 - 0.25</td><td align="center" valign="middle" >Bal.</td></tr></tbody></table></table-wrap><p>The XRD patterns were collected over 2θ range of 20˚ - 100˚ with a step size of 0.031˚. The subgrains structure and grain boundaries interaction in the UFG samples were studied using a transmission electron microscope (TEM; Model: FEI Technai) with a voltage of 200 kV and also using a Zeiss optical microscope. The fractured surfaces were investigated using SEM to observe the microscopic features of failure in each case. Microhardness measurements were also carried out on the central cross-section surface using a Vickers indenter at a load of 50 g and a dwell time of 10 s. Tensile tests at a strain rate of 1 mm/min were conducted using a UTS-type machine (S-series H25k-S Model) at an ambient temperature based on the ASTM: E8M standard.</p></sec><sec id="s3"><title>3. Results and Discussion</title><sec id="s3_1"><title>3.1. Microstructure Characterization</title><p>XRD scattering pattern results are depicted in <xref ref-type="fig" rid="fig1">Figure 1</xref>(a) representing the diffraction spectra of the RTF and the CF samples at 6 cycles. The magnified Al (111) peaks are also illustrated to accurately predict the microstructural changes. The existence of dispersed Al<sub>2</sub>Cu second phase particles throughout the Al matrix can be confirmed by peaks 2θ angles which matched with Al and Al<sub>2</sub>Cu phases’ standard locations. The basic reinforcing phases are Al<sub>2</sub>Cu in this alloy.</p><p>According to <xref ref-type="fig" rid="fig1">Figure 1</xref>(a), a comparison of the major Al (111) peaks in the magnified XRD patterns between the CF and RTF AA2519 samples shows that the Al peaks’ intensities were decreased and became broadened and shifted to smaller degrees through the cryoforging process which is a strong indicator of the alteration of the lattice parameters of the Al due to high internal lattice strain</p><p>and defects [<xref ref-type="bibr" rid="scirp.90293-ref22">22</xref>] [<xref ref-type="bibr" rid="scirp.90293-ref23">23</xref>] . The high crystallite refinement and lattice strain increment in the Al matrix occurred as the results of more effective SPD during the cryogenic process. In this case, the dynamic recovery is systematically stopped at the liquid nitrogen temperature which leads to diminishing dislocation mobility and allowing the accumulation of dislocation density to achieve a higher steady state level. Similar peak broadening and intensity reduction in UFG 6061 aluminum alloy during dissimilar channel angular pressing was observed by Tan et al. [<xref ref-type="bibr" rid="scirp.90293-ref24">24</xref>] .</p><p>The XRD analysis suggested that the intensity of the Al<sub>2</sub>Cu diffraction peaks in a RTF alloy was a little stronger than that in a CF alloy, indicating that the amount of Al<sub>2</sub>Cu precipitates after ambient process had increased. Higher thermal energy and increase of local temperature during forging at a room temperature may supply the driving force for the reaction between Al and Cu to form Al<sub>2</sub>Cu. Furthermore, the broadened Al<sub>2</sub>Cu peaks with lower intensity in the CF samples are also an indication of the second phase breakage to finer particles as a result of the induced high plastic strain through the forging process at cryogenic temperature. This process exerts a strong plastic deformation leading to the generation of more shear intense stress followed by the breaking down of the second phase particles. This Al<sub>2</sub>Cu particles breakage can be accompanied by redistribution through the Al matrix, which assured a more homogeneous microstructure and stronger mechanical strength. The fragmented Al<sub>2</sub>Cu particles in Al matrix after cryogenic deformation in the CF samples shown in <xref ref-type="fig" rid="fig1">Figure 1</xref>(b) confirms the data obtained from the XRD analysis. Adamczyk-Cieslak et al. [<xref ref-type="bibr" rid="scirp.90293-ref25">25</xref>] also observed the breaking and rearrangement of the precipitates in 2xxx aluminum alloys as a result of SPD.</p><p>The microstructure of grains/subgrains of the 6 cycles CF AA2519 was investigated through transmission electron micrographs in <xref ref-type="fig" rid="fig1">Figure 1</xref>(c) to realize the materials characteristics which were not possible to resolve via optical microscopy. As clearly shown in <xref ref-type="fig" rid="fig1">Figure 1</xref>(c), the grains were plastically deformed and were surrounded by high density of dislocations.</p><p>The severely deformed cells marked with arrows in <xref ref-type="fig" rid="fig1">Figure 1</xref>(c) are indication of the grains/subgrains size which falls within a nano-metric scale. The generation of this distorted nanoscale subgrains and the development of nanoscale deformation twins at locally accumulated grain boundaries show that cryogenic forging influences the microstructure of the material. This grain refinement and grain boundaries accumulation can be expected as a significant microstructural evolution while intense plastic strain corresponds with the restriction of dynamic recovery and recrystallization mechanisms. Atomic mismatch in the accumulated dislocation regions leads to the generation of a high plastic strain and deformations bands. Further strain makes the dislocation walls and tangles to transform into sub-boundaries with small misorientation in the original grains separating the individual cells or subgrains [<xref ref-type="bibr" rid="scirp.90293-ref26">26</xref>] . Chen et al. [<xref ref-type="bibr" rid="scirp.90293-ref21">21</xref>] studied equal-channel deformation of an Al-Mg alloy at cryogenic temperatures and reported such high-density dislocations distorted grains to a refining grain size. However, increase in strain in the RTF processing no longer results in grain refinement to nano/ultrafine size since the dislocation multiplication rate in the RTF processing is balanced by the annihilation rate. In addition, Cu solutes in the AA2519 alloy increase the stacking fault energy which may activate cross-slip mechanism. This mechanism suppresses dislocation climb and the rearrangement of lattice dislocations resulting in the formation of high strains and intense refinement in cell structure [<xref ref-type="bibr" rid="scirp.90293-ref27">27</xref>] .</p></sec><sec id="s3_2"><title>3.2. Mechanical Behavior</title><p>The stress-strain curves for the quasi-static tensile test results are shown in <xref ref-type="fig" rid="fig2">Figure 2</xref>. This section provides an overview of several aspects of the mechanical behavior of the RTF and CF processed materials in which the number of the forging cycles (2, 4 and 6) was considered as a variable parameter. In addition, the ultimate tensile strength (UTS), the percentage elongation and the toughness graphs for the tested samples are presented in <xref ref-type="fig" rid="fig3">Figure 3</xref> as a function of the forging cycles. To provide more quantitative data, the mechanical properties obtained from these curves along with the hardness measurement results from the Vickers indentation tests are also summarized in <xref ref-type="table" rid="table2">Table 2</xref>.</p><p>The stress-strain curves in <xref ref-type="fig" rid="fig2">Figure 2</xref>(a) and <xref ref-type="fig" rid="fig2">Figure 2</xref>(b) show that further forging process to the next cycles resulted in a significant increase in the UTS values for both CF and RTF samples. The UTS values increase by 33% and 26% when processed from 2 to 6 cycles for the RTF and the CF samples, respectively. This can be due to further crystallite size refinement at higher cycles of the SPD</p><table-wrap id="table2" ><label><xref ref-type="table" rid="table2">Table 2</xref></label><caption><title> The derived mechanical properties from stress-strain graphs plus hardness</title></caption><table><tbody><thead><tr><th align="center" valign="middle" >Materials</th><th align="center" valign="middle" >No. of Cycles</th><th align="center" valign="middle" >Ultimate Tensile Strength (MPa)</th><th align="center" valign="middle" >Elongation (%)</th><th align="center" valign="middle" >Toughness (MJ∙m<sup>−3</sup>)</th><th align="center" valign="middle" >Hardness (Hv)</th></tr></thead><tr><td align="center" valign="middle"  rowspan="3"  >RTF-AA2519</td><td align="center" valign="middle" >2</td><td align="center" valign="middle" >252</td><td align="center" valign="middle" >6.1</td><td align="center" valign="middle" >18.03</td><td align="center" valign="middle" >98</td></tr><tr><td align="center" valign="middle" >4</td><td align="center" valign="middle" >305</td><td align="center" valign="middle" >3.8</td><td align="center" valign="middle" >15.09</td><td align="center" valign="middle" >130</td></tr><tr><td align="center" valign="middle" >6</td><td align="center" valign="middle" >334</td><td align="center" valign="middle" >1.1</td><td align="center" valign="middle" >8.77</td><td align="center" valign="middle" >149</td></tr><tr><td align="center" valign="middle"  rowspan="3"  >CF-AA2519</td><td align="center" valign="middle" >2</td><td align="center" valign="middle" >356</td><td align="center" valign="middle" >9.0</td><td align="center" valign="middle" >32.45</td><td align="center" valign="middle" >165</td></tr><tr><td align="center" valign="middle" >4</td><td align="center" valign="middle" >415</td><td align="center" valign="middle" >6.8</td><td align="center" valign="middle" >30.06</td><td align="center" valign="middle" >198</td></tr><tr><td align="center" valign="middle" >6</td><td align="center" valign="middle" >449</td><td align="center" valign="middle" >5.4</td><td align="center" valign="middle" >29.14</td><td align="center" valign="middle" >221</td></tr></tbody></table></table-wrap><p>process. In fact, high volume of accumulated grain boundaries in the deformed materials acts as barriers for the movement of dislocations thereby preventing further deformation [<xref ref-type="bibr" rid="scirp.90293-ref28">28</xref>] . However, thermomechanical balance in kinetics of grains recrystallization and refinement led to a decrease in the strength enhancement from 4 to 6 cycles in comparison to processing from 2 to 4 cycles.</p><p>As expected, <xref ref-type="table" rid="table2">Table 2</xref> indicates a similar increasing trend for the hardness measurements with UTS. The correlation between hardness values and tensile strengths are often linear even though it strongly depends on the ability of the metals to strain harden especially in UFG materials which normally present a low level of strain hardening [<xref ref-type="bibr" rid="scirp.90293-ref29">29</xref>] .</p><p>Although, limited amount of changes were obtained by performing the forging process at higher cycles, the tensile profiles show much more significant influences on the mechanical properties of the CF materials than that of the RTF samples. The UTS values indicate that cryogenic processing creates materials with 41% higher strength after 2 cycles of MAF when compared with the samples processed at ambient temperature. In cryoforging, the strain-hardening is preserved up to the extent to which forging is done. This signifies that neither dislocation recovery nor recrystallization occurs during the entire SPD process whereas dynamic recovery and subsequent softening are inevitable in the materials under conventional forging. In other words, climb of dislocations and cross slip are extensively inhibited within the cryogenic process thereby accumulating high dislocation density which is not the case for ambient forging. Consequently, nanocrystalline/UFG microstructure with bi-modal grains is developed in the CF alloy resulting in high mechanical strength which is in consistence with the Hall-Petch strengthening mechanism. Similar increase in the UTS from 315 to 522 MPa was reported by Lee et al. [<xref ref-type="bibr" rid="scirp.90293-ref19">19</xref>] as a result of cryorolling of 5083 aluminum alloy while they observed 490 MPa for UTS after room temperature rolling with the same reduction. Meanwhile, the positive effect of the fractured second phases on the strength of CF samples should not be overlooked. They followed Orowan mechanism to hinder dislocation movements [<xref ref-type="bibr" rid="scirp.90293-ref30">30</xref>] .</p><p>It is widely known that the improvement of mechanical strength in SPD processed materials is followed by ductility reduction. According to <xref ref-type="fig" rid="fig3">Figure 3</xref>(a), the cryogenic forging does not only increase the UTS of the alloys but also improves the ductility of the materials in comparison with the RTF processed samples. Nonequilibrium grain boundaries in UFG metals have also been recognized as a significant factor to improve ductility [<xref ref-type="bibr" rid="scirp.90293-ref31">31</xref>] . High density of dislocations is exposed to slip which enables grains to slide or rotate. As it is well known, the ductility of a material is highly dependent on their structural homogeneity. It can be concluded that homogeneous grain microstructure with low aspect ratio in CF samples was developed during cryogenic forging due to the multi axial process corresponding with recrystallization suppression as well as a high degree of grain refinement.</p><p>It is worth paying attention to the lowering effect of additional forging cycles on the elongation at fracture for both the CF and the RTF alloys as can be seen in the strain-strain curves in <xref ref-type="fig" rid="fig3">Figure 3</xref>(a). This stems from highly limited strain hardening that causes localized deformation in the processed samples with prolonged forging. The accumulate dislocations for strain hardening is almost infeasible due to the refined crystallite size and saturation of dislocations [<xref ref-type="bibr" rid="scirp.90293-ref32">32</xref>] . However, the decreasing rate of ductility in the RFT samples was observed to be higher than that of the CF samples such that this reduction between 4 and 6 cycles were 54% and 23% for the RTF and the CF samples, respectively.</p><p>The stress-strain response of the nanocrystalline CF alloys under tension shows a rapid peak and subsequent softening due largely to necking. The reason for this strength drop can be attributed to the intrinsic feature of nanoscale materials. The high surface (grain boundaries) to volume ratio of the nanograins may facilitate their rotation with a lower stress. Plastic deformation makes the nanosized grains to rotate and consequently coalesce along the directions of shear generating larger paths for dislocation movement. This phenomenon is schematically explained in <xref ref-type="fig" rid="fig4">Figure 4</xref>. The orientations of the slip systems are depicted by a short line in each grain in this figure. Beyond the peak of the stress-strain curves, plastic deformation aligned neighboring grains in the same</p><p>orientation closer together. This may diminish their boundaries providing a path for more extended dislocation motion and may consequently lead to the softening behavior in the plastic zone [<xref ref-type="bibr" rid="scirp.90293-ref28">28</xref>] .</p><p>The toughness per unit volume of the RTF and the CF materials was computed for various forging cycles using the integration method to obtain the areas of the true stress-strain curves and was depicted in <xref ref-type="fig" rid="fig3">Figure 3</xref>(b) for detailed evaluation with a comparative view. As seen, significantly higher amount of deformation energy has been absorbed in the CF materials during the tensile test in comparison with the conventionally forged samples. Hence, the samples made by cryogenic forging possess higher level of toughness which can be ascribed to their high density of dislocations and grain boundary sliding in such UFG structure [<xref ref-type="bibr" rid="scirp.90293-ref33">33</xref>] .</p></sec><sec id="s3_3"><title>3.3. Fractography</title><p>The deformation behavior of the materials was identified by the microstructural characterization of failure mechanisms at the tensile rupture surfaces and diagnosing failure modes using SEM. Fractographs of the materials subjected to tensile deformation are presented in <xref ref-type="fig" rid="fig5">Figure 5</xref>. Similar to the stress-strain profiles, the variation of the forging cycles from 2 to 6 was considered since they significantly affected the tensile behavior of the materials. In such materials the polished morphology that distinguishes brittle regions as well as the size and depth of micro-dimples is typically characterized to be an indication of ductile zones which nucleated from the Al<sub>2</sub>Cu second phase particles. Furthermore, each dimple is an evidence of a crack nucleation site, which has been linked up during the plastic deformation process. The fractured surface of the CF samples processed via 6, 4 and 2 forging were shown in <xref ref-type="fig" rid="fig5">Figure 5</xref>(a) and <xref ref-type="fig" rid="fig5">Figure 5</xref>(c) and <xref ref-type="fig" rid="fig5">Figure 5</xref>(e) respectively. In the CF sample case, integration of mostly ductile domain</p><p>(marked with circles) and slight brittle fractured regions (showed with arrows) can be recognized while the small micro-dimples and polished morphology are visible on their fractured surfaces. Therefore, a typical ductile failure mode is present in the CF samples. However, less number of dimples with the reduced deep size is a clear proof of ductility reduction in the extended forging cycles which is in consistent with the stress-strain results. Rahmatabadi et al. [<xref ref-type="bibr" rid="scirp.90293-ref34">34</xref>] observed a similar increasing tensile strength and decreasing elongation by increasing the number of ARB cycles in the fractography of Aluminum.</p><p>On the other hand, a large area of polished morphology in <xref ref-type="fig" rid="fig5">Figure 5</xref>(b) imparts a brittle failure mode in RTF sample up to 6 forging cycles. This mode of rupture begins with microvoids formation and coalescence, crack growth and finally a shear fracture that leads to failure. <xref ref-type="fig" rid="fig5">Figure 5</xref>(d) and <xref ref-type="fig" rid="fig5">Figure 5</xref>(b) also show a considerable ductility reduction in the next cycles by a decrease in the number of deep dimples which can be attributed to highly stored internal strain while applying plastic deformation in the RTF samples.</p><p>The 6 cycle forged RTF samples have experienced a brittle fracture since no apparent plastic deformation took place as a result of tensile stress. Brittle fracture typically involves small energy absorption and occurs at high speeds. Also, a cleavage fracture surface is obvious on a part of this sample which is an indication of the brittle fracture caused by the normal stress to crystallographic planes with low bonding (cleavage planes). It is noted that conventional forging process makes fractured area with finer dimples which indicates lower ductility as compared to the CF materials with coarser and deeper dimples.</p></sec></sec><sec id="s4"><title>4. Conclusions</title><p>The following conclusions can be drawn from this study:</p><p>1) An integrated enhancement in mechanical strength, ductility and toughness of the AA2519 aluminum alloy was achieved as the result of cryogenic MAF process. This can be attributed to crystallite size refinement to nanoscales, heavily deformed grains with high density of grain boundaries and second phase breakage to finer particles observed through the XRD pattern and TEM micrographs of the cryogenic forging. Simultaneous SPD as well as the suppression of the dynamic recovery and recrystallization mechanisms during the cryogenic environment made the SPD process rather effective than performing the same process at room temperature.</p><p>2) The SEM micrographs of the fractured surfaces showed a significant ductility improvement in the CF materials which are in alignment with their stress-strain profiles. In addition, a slight increase in the tensile strength and a reduction in ductility are obtained in extended forging cycles due to less ability to accumulate dislocations. However, decreasing rate of ductility in the RFT samples was observed to be higher than that of the CF samples once proceeded to the next cycles.</p><p>Future study will focus on the effect of thermal treatments on the microstructure and mechanical response of the alloy after cryogenic forging in order to see the possibility of increasing the ductility of the processed alloy without any considerable strength loss.</p></sec><sec id="s5"><title>Acknowledgements</title><p>Financial support for this work was provided through contract # W911NF-15-1-0457 under the direct supervision of Patricia Huff (HBCU/MI Program Manager, ARO).</p></sec><sec id="s6"><title>Conflicts of Interest</title><p>The authors declare no conflicts of interest regarding the publication of this paper.</p></sec><sec id="s7"><title>Cite this paper</title><p>Azimi, A., Owolabi, G.M., Fallahdoost, H., Kumar, N. and Whitworth, H. (2019) Microstructure and Quasi-Static Mechanical Behavior of Cryoforged AA2519 Alloy. Materials Sciences and Applications, 10, 137-149. https://doi.org/10.4236/msa.2019.102011</p></sec></body><back><ref-list><title>References</title><ref id="scirp.90293-ref1"><label>1</label><mixed-citation publication-type="other" xlink:type="simple">Monteiro, W.A., da Silva, S.L.V., da Silva, L.V., de Andrade, A.H.P. and da Silva, L.C.E. (2017) Characterization of Nickel Alloy 600 with Ultra-Fine Structure Processed by Severe Plastic Deformation Technique (SPD). Journal of Materials Science and Chemical Engineering, 5, 33-44. https://doi.org/10.4236/msce.2017.54004</mixed-citation></ref><ref id="scirp.90293-ref2"><label>2</label><mixed-citation publication-type="other" xlink:type="simple">Zehetbauer, M.J. and Valiev, R.Z. (2006) Nanomaterials by Severe Plastic Deformation. John Wiley &amp; Sons, Hoboken.</mixed-citation></ref><ref id="scirp.90293-ref3"><label>3</label><mixed-citation publication-type="other" xlink:type="simple">Berndt, N., Frint, P. and Wagner, M.F.-X. (2018) Influence of Extrusion Temperature on the Aging Behavior and Mechanical Properties of an AA6060 Aluminum Alloy. Metals, 8, 51. https://doi.org/10.3390/met8010051</mixed-citation></ref><ref id="scirp.90293-ref4"><label>4</label><mixed-citation publication-type="other" xlink:type="simple">Fritsch, S. and Wagner, M.F.-X. (2018) On the Effect of Natural Aging Prior to Low Temperature ECAP of a High-Strength Aluminum Alloy. Metals, 8, 63. https://doi.org/10.3390/met8010063</mixed-citation></ref><ref id="scirp.90293-ref5"><label>5</label><mixed-citation publication-type="other" xlink:type="simple">Nejadseyfi, O., Shokuhfar, A., Azimi, A. and Shamsborhan, M. (2015) Improving Homogeneity of Ultrafine-Grained/Nanostructured Materials Produced by ECAP Using a Bevel-Edge Punch. Journal of Materials Science, 50, 1513-1522. https://doi.org/10.1007/s10853-014-8712-3</mixed-citation></ref><ref id="scirp.90293-ref6"><label>6</label><mixed-citation publication-type="other" xlink:type="simple">Khabushan, J.K. and Bonabi, S.B. (2017) Investigating of the Microstructure and Mechanical Properties of Al-Based Composite Reinforced with Nano-Trioxide Tungsten via Accumulative Roll Bonding Process. Open Journal of Metal, 7, 9-23. https://doi.org/10.4236/ojmetal.2017.71002</mixed-citation></ref><ref id="scirp.90293-ref7"><label>7</label><mixed-citation publication-type="other" xlink:type="simple">Song, Y., Wang, W., Gao, D., Kim, H.-S., Yoon, E.-Y., Lee, D.-J., Lee, C.-S. and Guo, J. (2012) Inhomogeneous Hardness Distribution of High Pressure Torsion Processed IF Steel Disks. Materials Sciences and Applications, 3, 234-239. https://doi.org/10.4236/msa.2012.34034</mixed-citation></ref><ref id="scirp.90293-ref8"><label>8</label><mixed-citation publication-type="other" xlink:type="simple">Chen, Q., Shu, D., Hu, C., Zhao, Z. and Yuan, B. (2012) Grain Refinement in an As-Cast AZ61 Magnesium Alloy Processed by Multi-Axial Forging under the Multitemperature Processing Procedure. Materials Science and Engineering: A, 541, 98-104. https://doi.org/10.1016/j.msea.2012.02.009</mixed-citation></ref><ref id="scirp.90293-ref9"><label>9</label><mixed-citation publication-type="other" xlink:type="simple">Cherukuri, B. and Srinivasan, R. (2006) Properties of AA6061 Processed by Multi-Axial Compressions/Forging (MAC/F). Materials and Manufacturing Processes, 21, 519-525. https://doi.org/10.1080/10426910500471649</mixed-citation></ref><ref id="scirp.90293-ref10"><label>10</label><mixed-citation publication-type="other" xlink:type="simple">Bruder, E. (2018) Mechanical Properties of ARMCO&amp;reg; Iron after Large and Severe Plastic Deformation—Application Potential for Precursors to Ultrafine Grained Microstructures. Metals, 8, 191. https://doi.org/10.3390/met8030191</mixed-citation></ref><ref id="scirp.90293-ref11"><label>11</label><mixed-citation publication-type="other" xlink:type="simple">Panigrahi, S.K., Jayaganthan, R. and Chawla, V. (2008) Effect of Cryorolling on Microstructure of Al-Mg-Si Alloy. Materials Letters, 62, 2626-2629. https://doi.org/10.1016/j.matlet.2008.01.003</mixed-citation></ref><ref id="scirp.90293-ref12"><label>12</label><mixed-citation publication-type="other" xlink:type="simple">Magalhaes, D.C.C., Kliauga, A.M., Ferrante, M. and Sordi, V.L. (2017) Plastic Deformation of FCC Alloys at Cryogenic Temperature: The Effect of Stacking-Fault Energy on Microstructure and Tensile Behaviour. Journal of Materials Science, 52, 7466-7478. https://doi.org/10.1007/s10853-017-0979-8</mixed-citation></ref><ref id="scirp.90293-ref13"><label>13</label><mixed-citation publication-type="other" xlink:type="simple">Ahn, B. (2018) Synthesis and Properties of Bulk Nanostructured Metallic Materials. Metals, 8, 855. https://doi.org/10.3390/met8100855</mixed-citation></ref><ref id="scirp.90293-ref14"><label>14</label><mixed-citation publication-type="other" xlink:type="simple">Nejadseyfi, O., Shokuhfar, A., Dabiri, A. and Azimi, A. (2015) Combining Equal-Channel Angular Pressing and Heat Treatment to Obtain Enhanced Corrosion Resistance in 6061 Aluminum Alloy. Journal of Alloys and Compounds, 648, 912-918. https://doi.org/10.1016/j.jallcom.2015.05.177</mixed-citation></ref><ref id="scirp.90293-ref15"><label>15</label><mixed-citation publication-type="other" xlink:type="simple">Longtin, R., Hack, E., Neuenschwander, J. and Janczak-Rusch, J. (2011) Benign Joining of Ultrafine Grained Aerospace Aluminum Alloys Using Nano-technology. Advanced Materials, 23, 5812-5816. https://doi.org/10.1002/adma.201103275</mixed-citation></ref><ref id="scirp.90293-ref16"><label>16</label><mixed-citation publication-type="other" xlink:type="simple">Suryanarayana, C. (1994) Structure and Properties of Nanocrystalline Materials. Bulletin of Materials Science, 17, 307-346. https://doi.org/10.1007/BF02745220</mixed-citation></ref><ref id="scirp.90293-ref17"><label>17</label><mixed-citation publication-type="other" xlink:type="simple">Hansen, N. (2004) Hall-Petch Relation and Boundary Strengthening. Scripta Materialia, 51, 801-806. https://doi.org/10.1016/j.scriptamat.2004.06.002</mixed-citation></ref><ref id="scirp.90293-ref18"><label>18</label><mixed-citation publication-type="other" xlink:type="simple">Ivanov, K.V. and Naydenkin, E.V. (2012) Grain Boundary Sliding in Ultrafine Grained Aluminum under Tension at Room Temperature. Scripta Materialia, 66, 511-514. https://doi.org/10.1016/j.scriptamat.2011.12.039</mixed-citation></ref><ref id="scirp.90293-ref19"><label>19</label><mixed-citation publication-type="other" xlink:type="simple">Lee, Y.B., Shin, D.H., Park, K.-T. and Nam, W.J. (2004) Effect of Annealing Temperature on Microstructures and Mechanical Properties of a 5083 Al Alloy Deformed at Cryogenic Temperature. Scripta Materialia, 51, 355-359. https://doi.org/10.1016/j.scriptamat.2004.02.037</mixed-citation></ref><ref id="scirp.90293-ref20"><label>20</label><mixed-citation publication-type="other" xlink:type="simple">Vendra, S.S.L., Goel, S., Kumar, N. and Jayaganthan, R. (2017) A Study on Fracture Toughness and Strain Rate Sensitivity of Severely Deformed Al 6063 Alloys Processed by Multiaxial Forging and Rolling at Cryogenic Temperature. Materials Science and Engineering: A, 686, 82-92. https://doi.org/10.1016/j.msea.2017.01.035</mixed-citation></ref><ref id="scirp.90293-ref21"><label>21</label><mixed-citation publication-type="other" xlink:type="simple">Chen, Y.J., Roven, H.J., Gireesh, S.S., Skaret, P.C. and Hjelen, J. (2011) Quantitative Study of Grain Refinement in Al-Mg Alloy Processed by Equal Channel Angular Pressing at Cryogenic Temperature. Materials Letters, 65, 3472-3475. https://doi.org/10.1016/j.matlet.2011.07.067</mixed-citation></ref><ref id="scirp.90293-ref22"><label>22</label><mixed-citation publication-type="other" xlink:type="simple">Azimi, A., Shokuhfar, A. and Zolriasatein, A. (2014) Nanostructured Al-Zn-Mg-Cu-Zr Alloy Prepared by Mechanical Alloying Followed by Hot Pressing. Materials Science and Engineering: A, 595, 124-130. https://doi.org/10.1016/j.msea.2013.11.094</mixed-citation></ref><ref id="scirp.90293-ref23"><label>23</label><mixed-citation publication-type="other" xlink:type="simple">Azimi, A., Fallahdoost, H. and Nejadseyfi, O. (2015) Microstructure, Mechanical and Tribological Behavior of Hot-Pressed Mechanically Alloyed Al-Zn-Mg-Cu Powders. Materials &amp; Design, 75, 1-8. https://doi.org/10.1016/j.matdes.2015.03.011</mixed-citation></ref><ref id="scirp.90293-ref24"><label>24</label><mixed-citation publication-type="other" xlink:type="simple">Tan, E., Kibar, A.A. and Gür, C.H. (2011) Mechanical and Microstructural Characterization of 6061 Aluminum Alloy Strips Severely Deformed by Dissimilar Channel Angular Pressing. Materials Characterization, 62, 391-397. https://doi.org/10.1016/j.matchar.2011.01.016</mixed-citation></ref><ref id="scirp.90293-ref25"><label>25</label><mixed-citation publication-type="other" xlink:type="simple">Adamczyk-Cieslak, B., Zdunek, J. and Mizera, J. (2016) Evolution of Microstructure and Precipitates in 2xxx Aluminum Alloy after Severe Plastic Deformation. IOP Conference Series: Materials Science and Engineering, 123, 1-4. https://doi.org/10.1088/1757-899X/123/1/012019</mixed-citation></ref><ref id="scirp.90293-ref26"><label>26</label><mixed-citation publication-type="other" xlink:type="simple">Azadmanjiri, J., Berndt, C.C., Kapoor, A. and Wen, C. (2015) Development of Surface Nano-Crystallization in Alloys by Surface Mechanical Attrition Treatment (SMAT). Critical Reviews in Solid State and Materials Sciences, 40, 164-181. https://doi.org/10.1080/10408436.2014.978446</mixed-citation></ref><ref id="scirp.90293-ref27"><label>27</label><mixed-citation publication-type="other" xlink:type="simple">Zuiko, I. and Kaibyshev, R. (2017) Deformation Structures and Strengthening Mechanisms in an Al-Cu Alloy Subjected to Extensive Cold Rolling. Materials Science and Engineering: A, 702, 53-64. https://doi.org/10.1016/j.msea.2017.07.001</mixed-citation></ref><ref id="scirp.90293-ref28"><label>28</label><mixed-citation publication-type="other" xlink:type="simple">Meyers, M.A., Mishra, A. and Benson, D.J. (2006) Mechanical Properties of Nanocrystalline Materials. Progress in Materials Science, 51, 427-556. https://doi.org/10.1016/j.pmatsci.2005.08.003</mixed-citation></ref><ref id="scirp.90293-ref29"><label>29</label><mixed-citation publication-type="other" xlink:type="simple">Pavlina, E.J. and Van Tyne, C.J. (2008) Correlation of Yield Strength and Tensile Strength with Hardness for Steels. Journal of Materials Engineering and Performance, 17, 888-893. https://doi.org/10.1007/s11665-008-9225-5</mixed-citation></ref><ref id="scirp.90293-ref30"><label>30</label><mixed-citation publication-type="other" xlink:type="simple">Queyreau, S., Monnet, G. and Devincre, B. (2010) Orowan Strengthening and Forest Hardening Superposition Examined by Dislocation Dynamics Simulations. Acta Materialia, 58, 5586-5595. https://doi.org/10.1016/j.actamat.2010.06.028</mixed-citation></ref><ref id="scirp.90293-ref31"><label>31</label><mixed-citation publication-type="other" xlink:type="simple">Valiev, R.Z., Alexandrov, I.V., Zhu, Y.T. and Lowe, T.C. (2002) Paradox of Strength and Ductility in Metals Processed Bysevere Plastic Deformation. Journal of Materials Research, 17, 5-8. https://doi.org/10.1557/JMR.2002.0002</mixed-citation></ref><ref id="scirp.90293-ref32"><label>32</label><mixed-citation publication-type="other" xlink:type="simple">Gong, Y.L., Wen, C.E., Li, Y.C., Wu, X.X., Cheng, L.P., Han, X.C. and Zhu, X.K. (2013) Simultaneously Enhanced Strength and Ductility of Cu-xGe Alloys through Manipulating the Stacking Fault Energy (SFE). Materials Science and Engineering: A, 569, 144-149. https://doi.org/10.1016/j.msea.2013.01.022</mixed-citation></ref><ref id="scirp.90293-ref33"><label>33</label><mixed-citation publication-type="other" xlink:type="simple">Das, P., Jayaganthan, R. and Singh, I.V. (2011) Tensile and Impact-Toughness Behaviour of Cryorolled Al 7075 Alloy. Materials &amp; Design, 32, 1298-1305. https://doi.org/10.1016/j.matdes.2010.09.026</mixed-citation></ref><ref id="scirp.90293-ref34"><label>34</label><mixed-citation publication-type="other" xlink:type="simple">Rahmatabadi, D., Hashemi, R., Mohammadi, B. and Shojaee, T. (2017) Experimental Evaluation of the Plane Stress Fracture Toughness for Ultra-Fine Grained Aluminum Specimens Prepared by Accumulative Roll Bonding Process. Materials Science and Engineering: A, 708, 301-310. https://doi.org/10.1016/j.msea.2017.09.085</mixed-citation></ref></ref-list></back></article>