DSC study of precipitation in an Al–Mg–Mn alloy microalloyed with Cu

Starink, M.J.; Dion, A.

doi:10.1016/j.tca.2004.01.013

Cited by 20 publications

(10 citation statements)

References 27 publications

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“…Bookmark not defined.] and references therein, and references [10,11,13,[15][16][17][18][19][20][21][22]44,51,52,53,65]), and concluded that the present model is consistent with all the available data. In particular it should be noted that no microstructure investigation ever showed evidence for precipitates (other than co-clusters suggested by APFIM, 3DAP) for ageing times within about 10 times the time to reach the plateau hardness (or time to stabilise the enthalpy).…”

Section: Nanostructure Data and Quantum Mechanical Modellingsupporting

confidence: 80%

“…Further corrections for imperfections of the DSC as well as correction for the heat capacity contribution not related to reactions of the samples is needed [43]. The optimum choice for this correction is alloy dependent and was considered in [44]. For the Cu-lean alloys 1 and 2, further correction was achieved by subtracting a linear function of T fitted to the initial part of the curve, where no reactions are thought to occur.…”

Section: Methodsmentioning

confidence: 99%

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The thermodynamics of and strengthening due to co-clusters: General theory and application to the case of Al–Cu–Mg alloys

2009

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Co-clusters in ternary or higher order metallic alloys are metastable structures involving two or more distinct alloying atoms that retain the structure of the host lattice. A thermodynamic model based on a single interaction energy of dissimilar nearest neighbour interaction energy is presented, and a model for the strengthening due to these co-cluster dimers is derived. The model includes a new treatment of (short-) order strengthening relevant to these co-clusters and further encompasses modulus hardening and chemical hardening. The models are tested against data on a wide range of Al-Cu-Mg alloys treated at temperatures between 20 and 220ºC. Both quantitative calorimetry data on the enthalpy change due to co-cluster formation and strengthening due to co-clusters is predicted well. It is shown that in general (short-range) order strengthening will be the main strengthening mechanism.

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Section: Nanostructure Data and Quantum Mechanical Modellingsupporting

confidence: 80%

Section: Methodsmentioning

confidence: 99%

The thermodynamics of and strengthening due to co-clusters: General theory and application to the case of Al–Cu–Mg alloys

2009

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“…The model is limited to considering two precipitates. These are the precipitate responsible for peak strength in Al-Si-Mg based alloys, β″ phase [17,18,19], and the precipitate responsible for peak strength in Al-Cu-Mg based alloys, S phase [15,20,21,22]. In support it is noted that quaternary Al-Mg-Si-Cu precipitates (see e.g.…”

Section: Precipitation Modelmentioning

confidence: 94%

Age hardening and softening in cold-rolled Al–Mg–Mn alloys with up to 0.4wt% Cu

Zhu

Starink

2008

Materials Science and Engineering: A

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The age hardening and age softening of nine solution treated and subsequently cold-rolled Al-(1-3)Mg-(0-0.4)Cu-0.15Si-0.25Mn (in wt%) alloys with potential applications in both packaging and automotive industries have been investigated. Cold work levels were 10, 40 and 90% reduction.The proof strengths of the aged alloys range from 130 to 370MPa. A physically based model for yield strength has been developed which includes a one parameter dislocation evolution model to describe work hardening and recovery and a two precipitate precipitation hardening model. The model is based on analytical equations, avoiding computing time intensive iterative schemes. An exceptionally high model accuracy has been demonstrated. The model parameters are verified by transmission electron microscopy and calorimetry analysis of the materials. IntroductionThe main strengthening mechanisms in aluminium alloys are work hardening, solution strengthening and precipitation strengthening, and in many cases one of these mechanisms is dominant. In most applications of Al-Mn based (3XXX) and Al-Mg based (5XXX) alloys both work hardening and solution strengthening are important contributors, and small Cu additions can improve the strength due to some limited precipitation hardening. These types of alloys have been widely used in beverage cans for decades [1], and aluminium alloys are increasingly being used as car body panels to reduce weight and thus improve fuel economy and emissions [2]. For this application 5XXX with Cu additions are very promising candidates for these applications because of their excellent formability, good strength and the benefits of precipitation hardening during paintbaking due to Cu additions [3,4,5].The alloys used for the above-mentioned canstock and automotive applications are generally warm or cold rolled to achieve thin gauge. During the processing of alloys with Cu additions, precipitation of strengthening phases occurs during hot and cold rolling as well as during heat treatment after cold rolling [6]. In both cases, precipitation will change the yield stress and the work hardening, which will affect subsequent further working of the alloys. In the case of beverage can applications, the cold rolled alloys are used in a work hardened condition, but for the car body application, they will be supplied to car manufacturers with O temper (annealed) due to the higher requirement of excellent formability during car body forming. For both applications, a further elevated temperature process in the form of coating/painting and baking are needed. Both recovery and precipitation will occur during these processes.From the above it will be apparent that understanding of the composition-processing-property relations in Al-Mg-Mn based alloys with Cu additions is important. In the present paper we will present data on the strength of nine cold rolled and subsequently aged Al-Mg-Mn alloys with up to 0.4wt%Cu. The strength will be analysed, and a physically based model for the strength will be presented.Physically-base...

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“…To provide an alternative estimate of the magnitude of the heat effect we propose the following semi-quantitative comparisons. Estimates based on a regular solution model outlined in [ 32 ], indicate that about 90% of the Mg present in the Al-1.9Cu-1.6Mg alloy can precipitate as Cu-Mg co-clusters during a DSC run 1 . Then the enthalpy of formation in the Al-1.9Cu-1.6Mg alloy is 14 J/g × 27.5 g/mol/(0.016 × 0.9) = 0.27 eV per Mg atom 2 .…”

Section: The Heat Evolution Due To Cu-mg Co-clustersmentioning

confidence: 99%

Reply to the comments on “Room-temperature precipitation in quenched Al–Cu–Mg alloys: a model for the reaction kinetics and yield-strength development”

Starink

Cerezo

Yan

et al. 2006

Philosophical Magazine Letters

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Our recent work on Al-Cu-Mg -based alloys with Cu:Mg ratio close to unity showed that the rapid hardening at room temperature and the substantial heat evolution arise from the formation of Cu-Mg co-clusters. Here, it is shown that the measured enthalpy of formation of clusters (~0.3eV per Mg atom) is in reasonable agreement with expectations based on the similarity with Mg-vacancy clusters. The origin of the term GPB zones, as applied to the rapid hardening in Al-Cu-Mg -based alloys, is investigated. It is shown that current knowledge on the nanostucture and microstructure development during rapid hardening can be described without recourse to this alloy-specific term. Analysis of the kinetics of Cu-Mg co-cluster formation by DSC indicates that the formation of CuMg co-clusters during a fast water quench can be sufficiently suppressed to cause substantial nucleation of co-clusters to occur in subsequent natural ageing and artificial ageing at low temperatures.In this reply to [1], which contains some comments on our paper [2], we would like to discuss a number of issues pertinent to points raised by Zahra et al. in the course of their paper. Before we deal with these we first want to note that much of [1] is taken up by a literature review and by a review of calorimetry data, which do not contradict our work. We will not comment on this but we do need to stress that the final interpretation by Zahra et al.[1] "[..] plate-like GPB zones which nucleate on clusters of irregular shape are responsible for the first hardening stage" is inconsistent with our three-dimensional atom probe (3DAP), differential scanning calorimetry (DSC) and hardness data on the two alloys we studied (Al-1.2Cu-1.2Mg and the Al-1.9Cu-1.6Mg (at%)): our 3DAP data shows that neither of these alloys contain substantial numbers of platelet or rod-like structures such as GPB zones during several days ageing at room temperature, whilst the hardness increase and heat evolution is completed within about one day. We will show that all the data and theoretical considerations expressed in [1], as well as data in papers cited in [1], are fully consistent with our conclusions. Specifically we need to note that nowhere in [1], or in any of the papers cited therein, is any nano/microstructural data presented that show platelet or rod-shaped GPB zones within Al-Cu-Mg alloy samples with compositions and heat treatments near the ones we have studied. We believe that there is no conclusive microstructural data having the necessary resolution on Al-Cu-Mg alloys with both Cu and Mg contents in excess of 1at%, heat treated to times up to 5 ×

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DSC study of precipitation in an Al–Mg–Mn alloy microalloyed with Cu

Cited by 20 publications

References 27 publications

The thermodynamics of and strengthening due to co-clusters: General theory and application to the case of Al–Cu–Mg alloys

The thermodynamics of and strengthening due to co-clusters: General theory and application to the case of Al–Cu–Mg alloys

Age hardening and softening in cold-rolled Al–Mg–Mn alloys with up to 0.4wt% Cu

Reply to the comments on “Room-temperature precipitation in quenched Al–Cu–Mg alloys: a model for the reaction kinetics and yield-strength development”

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