Microstructural evolution over a large strain range in aluminium deformed by cyclic-extrusion–compression

Materials Science and Engineering A260 (1999) 275 – 283

Microstructural evolution over a large strain range in aluminium deformed by cyclic-extrusion–compression M. Richert a, Q. Liu b,*, N. Hansen b a

Department of Structure and Mechanics of Solids, Uni6ersity of Mining and Metallurgy, PL-059, Krakow, Poland b Materials Research Department, Risø National Laboratory, DK-4000, Roskilde, Denmark Received 20 April 1998; received in revised form 28 July 1998

Abstract Polycrystalline pure aluminium (99.99%) has been deformed at room temperature by the Cyclic-Extrusion– Compression (CEC)-method to strains in the range 0.9–60 (1–67 cycles). At different strains, the microstructure and local crystallography have been characterised in particular by transmission electron microscopy. It has been found that the microstructure develops from a cell block structure into an almost equiaxed structure of cells and subgrains, that the spacing between the boundaries subdividing the structure is almost unaffected by the strain and that the misorientation across these boundaries increases with the strain over the whole strain range. At the largest strain, the average misorientation across the deformation induced boundaries is 25°. The flow stress in compression is measured after the cyclic deformation and it is found that the flow stress increases with strain towards a saturation level which is reached at a relatively low strain. The discussion comprises the effect of deformation mode and plastic strain over a large strain range on the microstructural evolution and mechanical behaviour of aluminium. © 1999 Elsevier Science S.A. All rights reserved. Keywords: Cyclic-extrusion–compression; Aluminium; Microstructure; Plasticity; Large-strain deformation

1. Introduction The microstructural and mechanical response to large strain deformation has been studied over many years [1–7]. This reflects that large strain behaviour is of both fundamental and technological importance [6]. Most of these studies have been carried out on specimens deformed in monotonic loading over a strain range extending up to 6 – 7 [4]. It is of interest to extend this strain range by introducing alternative deformation modes. This has been done in the present work concentrating on specimens deformed by the Cyclic-Extrusion–Compression (CEC)-method [5]. The CEC-method was invented to allow arbitrarily large strain deformation of a sample with the preservation of the original sample shape and the deformed specimens to be examined extensively [5,8,9]. For example, the microstructure evolution has been studied by optical metallography and Transmission Electron Microscopy (TEM), the texture has been measured by * Corresponding author. Tel.: +45-4677-5808; fax: +45-46775758; e-mail: [email protected].

X-rays, the flow stress (0.2% offset) has been measured in compression and the microhardness has been measured on the deformed specimens. Some of these results will be recapitulated in this paper together with new results mainly describing the effect of strain on microstructures and local crystallography, especially the angle of misorientation across dislocation boundaries and grain boundaries. The principal experimental technique has been TEM including Kikuchi pattern analysis. The material investigated has been polycrystalline pure aluminium (99.99%). The specimens have been deformed at room temperature over a very large strain range of o= 0.9–60, thereby allowing a comparison with previous experiments [5,8,9].

2. Experimental procedures

2.1. Deformation method The CEC-method is a combination of extrusion and compression which alternate (Fig. 1). The sample is

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placed in a sectioned die marked (1) on Fig. 1 consisting of an upper and lower chamber of equal diameters do. The chambers are connected by a channel of diameter dm. The two halves of the sectioned die (1) are connected by the screws (4) and (5) and are fixed to the frame (6) by bolts (7) and (8). The frame (6) is connected via the cantilever (9) to the stationary beam of the testing machine, whereas the inner frame (10) with the thrust screws (11) and (12) is connected via the cantilever (13) to the cross-head of the machine. The deformation proceeds by a cyclic flow of the metal from one chamber to the other. For example in a particular cycle, the sample is extruded from the upper to the lower chamber by the upper punch (2). Here, under the action of the lower punch (3) compression occurs simultaneously with the extrusion, so that the sample is restored to its initial shape. Before the beginning of the deformation process, the sample is compressed by the thrust screws (11) and (12). In this way, the sample is stressed in hydrostatic compression permitting arbitrarily high deformations without crack development. The magnitude of the cumulated true strain is approximately:

do o = 4n ln , dm where, do, is the chamber diameter, dm, the channel diameter and, n is the number of deformation cycles [5].The correct conditions of deformation during the cyclic deformation is controlled by continuous registration of the tension and compression forces. In the present experiment do and dm are 10 and 8 mm, respectively. This gives a strain of o= 0.9 per cycle.

2.2. Sample preparation and experiment High purity (99.99%) samples (28 mm long and 10 mm in diameter) with a grain size of  1.7 mm have been deformed in the strain range 0.9–60, corresponding to a range of cycles from 1 to 67. The cross-head speed has been 0.17 mm s − 1. The temperature during deformation has been measured by a thermocouple positioned close to the channel between the upper and the lower dies. The duration of the individual cycles ( 100 s) was chosen so that the temperature did not exceed room temperature by more than  10°C during the deformation process [8]. On the deformed sample, the flow stress (0.2% offset) in compression was measured on cylindrical specimens with a diameter of 8 mm and a height of 8 mm. The cross-head speed used was 0.017 mm s − 1 and the loading direction was the same as the extrusion direction. Longitudinal sections for microscopy and microhardness (mHV) testing were obtained by bisecting the deformed specimen by spark machining. For optical microscopy the specimens were electrolytically polished in a 20% HClO4 +C2H5OH reagent and then etched in the Keller reagent. Thin foils for electron microscopy were prepared from the longitudinal section. Local misorientations were measured by the Kikuchi pattern techniques in a TEM [10]. Texture measurements have previously been carried out by X-rays and the results are reported and discussed in detail in [11]. Generally, it is observed that the texture intensity does not appear to increase as the strain is increased in the large strain regime. However, the texture spread increases with the strain, but this effect is not large [11].

3. Results

3.1. Flow stress and hardness

Fig. 1. Equipment for deformation of metals by the Cyclic-Extrusion – Compression (CEC)-method [5].

The flow stress (0.2% offset) is shown in Fig. 2 as a function of the strain. After a strain of 0.9, the flow stress is 65 MPa and increases to a saturation value of  77 MPa which is reached in the strain range o= 5–8. The microhardness as a function of the strain is

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Fig. 2. Flow stress as a function of the accumulated strain. This curve also includes two data points obtained at strains lower than 0.9. These specimens have been deformed half a cycle and one cycle with a ratio do /dm =10/9 which gives strains 0.2 and 0.4, respectively.

shown in Fig. 3. The hardness changes correspond to the changes in flow stress. At large strain a slight decrease in hardness appears to take place as the strain increases in the range o = 4 – 20. Above this strain, the hardness is unaffected by the strain up to 60, which is the maximum strain examined. A comparison of Figs. 2 and 3 shows that the hardness is proportional to the flow stress with a proportional factor of 0.3. The specimens for electron microscopy have been examined  9 years after the deformation took place. The specimens have been stored at room temperature and the hardness measurements have been repeated to detect if changes have occurred during the long storage. This check was necessary as equipment was not available for repetition of the deformation process. The hardness data shows that the hardness has decreased by  10–20 hardness units. This decrease is larger than can be explained by the uncertainty of the measurements. The hardness decrease appears to be indepen-

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dent of strain, thus the hardness evolution with strain is quite similar before and after storage. The hardness measurement indicates that some recovery has taken place during storage. As this recovery appears to be independent of the strain it is believed that the microstructural examination of the stored specimens will give a reliable description of the microstructural changes caused by the deformation process itself. This assumption has been examined by comparing early microscopic work from the group which produced the specimens. The present work shows that the structure of the specimen stored for 9 years after deformation is very similar to the structure of the newly deformed specimens observed in [8] with respect to both morphology and the measured dislocation boundary spacing.

3.2. Macrostructure Fig. 4 shows the macrostructure observed in longitudinal sections of samples deformed at strains in the range 3.6–30.3. It is apparent that the original equiaxed grain structure is partly maintained even at the largest strain examined (Fig. 4(d)). The most typical feature is a banded structure indicating localized deformation in slip bands and shear bands. Fig. 4(a) shows short bands on the grain scale which have a direction with respect to the loading direction which varies from grain to grain. At the larger strains (Fig. 4(c)) intersecting bands appear with a length corresponding to the specimen dimension. These bands have an angle of  65° to the sample axis. Based on their length and their macroscopic orientation these bands have been identified as macroscopic shear bands [5,8,9]. A comparison of Fig. 4(b) and (c) shows that the number of shear bands increases when the strain is increased from 4.5 to 22.5. However, a comparison of Fig. 4(c) and (d) indicated that the tendency to form shear bands is reduced as the strain is further increased (in the present case to 30.6).

Fig. 3. Microhardness as a function of the accumulated strain.

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Fig. 4. Macrostructure in the longitudinal section at different accumulated strains: (a) 3.6; (b) 4.;5; (c) 22.5; (d) 30.6. The extrusion direction is marked ED [12].

3.3. Microstructure (TEM) The microstructure at low strain (o =0.9) shown in Fig. 5 is a characteristic deformation structure with extended Dense Dislocation Walls (DDWs) and Mi-

crobands (MBs) [12]. The DDW/MBs bound cell blocks containing ordinary dislocation cells. Within many of the cells dislocation tangles can be observed. The banded structure observed by TEM shows no relationship to the banded structure observed optically

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indicating localized deformation in slip bands and shear bands. Localized deformation indicated by the presence of S-bands, which is composed of many sets of Sshaped dislocation boundaries, in the TEM-microstructure has, however, been reported previously [5,9] in CEC-deformed commercial purity aluminium (99.5%). At increasing strains, the structure gradually evolves into an equiaxed cell/subgrain structure, where cell boundaries are less well formed, dislocation boundaries and subgrain boundaries are characterized by being well formed, sharp boundaries. This is illustrated in Fig. 6 showing the structure of a sample after a strain of 60 (67 cycles). Also this structure contains dislocation tangles in the interior of the cells/subgrains. This evolution from a banded to an equiaxed structure takes place gradually as a slightly banded structure is still observed after strains of 22 and 30. An example of this transition structure is shown in Fig. 7 for a specimen deformed to a strain of 30 (33 cycles). None of the specimens examined showed indications of dynamic or static recrystallization. The spacing (Dr) between the boundaries in the deformed structure has been determined by counting the number of intersections between the boundaries and a random set of test lines in the longitudinal plane [13]. The average spacing as a function of the true strain is shown in Fig. 8. This figure shows that the spacing in the range 1.2 – 1.4 mm is almost independent of the strain over the whole strain range taking into account that the standard deviation of the spacing is 10%. The misorientation angle (u) across the boundaries in the deformed microstructure was determined by a Kikuchi pattern analysis in the TEM [10]. Approxi-

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mately 200 boundaries are analyzed at each strain. After a strain of 0.9, all angles are below 10° with the majority being below 2° as shown in Fig. 9(a). With increasing strains, the average misorientation angle increases and the angular spread increases. Fig. 9(b) shows an example of a specimen deformed to a strain of  30. This figure shows that a substantial fraction of the boundaries can be characterized as high angle boundaries with an angle above 15°. Finally, at a strain of 60, Fig. 9(c) shows that approximately two thirds of the boundaries have developed into being high angle boundaries. The presence of both low angle and high angle boundaries in the microstructure is illustrated in Fig. 10 showing the structure of a specimen deformed to a strain of 30. It is characteristic that low and high angle boundaries are observed quite randomly distributed in the structure.

4. Discussion

4.1. Deformation mode Deformation by the CEC-method gives the possibility of deforming to very large cumulative plastic strains without sample shape changes. However, the method is cyclic, i.e. the strain direction changes from one half cycle to the next. A comparison with, e.g. monotonic loading is therefore not straightforward. For that reason, we shall first compare the present observations with previous studies where a changing strain direction has been applied, e.g. by cyclic loading in tension–compression of pure aluminium [14] and multidirectional

Fig. 5. Thin foil from a longitudinal section of a specimen deformed to a strain of 0.9 (one cycle). An area shows narrow, long DDW/MBs forming cell blocks containing ordinary dislocation cells. The extrusion direction is marked ED.

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Fig. 6. Thin foil from a longitudinal section of a specimen deformed to a strain of 60 (66 cycles). The area shows an equiaxed cell/subgrain structure. The extrusion direction is marked ED.

compression of commercial purity aluminium [15]. In these studies as in the present one, it has been observed that the microstructure after a substantial accumulated strain has a visual appearance typical of a high stacking fault energy material deformed at a relatively high homologous temperature, i.e. the structure looks like a warm worked (or a recovered) structure containing many subgrain boundaries. However, a quantitative analysis is required to underpin these qualitative observations. As concerns the flow stress it has been found [14,15] that it saturates at a relatively low strain and is constant from this strain up to the quite large strains which have been applied. It is also found that the stress at which the strain hardening rate is zero increases with an increase in the amplitude of the plastic strain leading to a refinement of the microstructure [14,15]. Quantitatively, the observations agree with the present ones with respect to the evolution both in microstructure and in flow stress. Most studies on highly deformed aluminium have applied monotonic loading, e.g. rolling or wire drawing [4,16,17]. It is therefore of interest to compare briefly the effect of monotonic deformation with deformation under a changing strain direction. Firstly, it is apparent that the deformation microstructure at small strains is quite comparable, as will be discussed in the next subsection. However, at increasing strain, the microstructure under monotonic loading develops into a structure where the cell/subgrain boundaries have a macroscopic orientation with respect to the specimen

axis, e.g. in rolling a lamella structure parallel to the rolling plane is a characteristic structure after large reductions of thickness. This is in contrast to the evolution towards an equiaxed cell/subgrain structure observed in specimens deformed under a changing strain direction. However, as smaller strains are generally applied in monotonic loading, it cannot be ruled out that at sufficiently high strains this deformation mode can also lead to a transformation of the directional structure into an equiaxed one. That such a structural transformation will take place has however not been found experimentally. Both in pure (99.996%) alu-

Fig. 7. Thin foil from a longitudinal section of a specimen deformed to a strain of 30 (33 cycles). An area shows an almost equiaxed cell/subgrain structure. The extrusion direction is marked ED.

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Fig. 8. Spacing between boundaries as a function of the accumulated strain.

minium [12] and in commercial purity aluminium [4], it has been found in longitudinal section of specimen cold-rolled to a thickness strain of o = 2.3 that a well defined lamellar structure has formed with lamellar boundaries almost parallel to the rolling plane. To do such observation at high strain is however not straightforward owing to the experimental difficulty of preparing edge-on TEM foils from specimens with a very small cross section. Finally, our brief comparison of monotonic loading with deformation under a changing strain direction shows that a saturation stress is not reached in monotonic loading even at strains in the range of 6 to 7 [4] and that the flow stress in monotonic loading for a similar total strain is higher than the saturation flow stress observed when deforming under a changing strain direction.

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significantly by the accumulated strain. In contrast, the misorientation across the boundaries is significantly affected by the strain as both the average misorientation angle and the angular spread increase with the strain (Fig. 9). What is noteworthy is the gradual decrease in the number of low angle boundaries (uB 4°) and the increase in the number of high angle boundaries (u\ 15°). Such a shift in the distribution has also been observed in monotonic deformation where the strain is increased to a value in the range 3–4 [19]. It can be noticed that although the angular distribution shifts with increasing strain, the fraction of low and medium angle boundary (B 15o) is still quite large at a strain of 60. This shows that the structure is significantly different from that of a typically polycrystalline metal, where the grain structure is obtained by deformation and recrystallization.

4.2. Microstructural e6olution In general, it is observed at low strain that the microstructure is subdivided by extended DDW/MBs forming cell blocks containing ordinary dislocation cells. This structure has a visual appearance typical for aluminium deformed monotonically, e.g. in rolling [12,17] or in tension [18]. At increasing deformation, this banded structure develops slowly into an equiaxed structure. It has been suggested [9,11] that localized glide and shear are underlying processes for this transformation, e.g. that crossing shear bands lead to fragmentation of the elongated microstructure characteristic for the low and medium strain regime. In this connection it will be of importance to examine more closely, how the tendency to form shear bands is affected by the evolving deformation microstructure. This is because, as seen in Fig. 4, it cannot be ruled out that the tendency to localized shear may be reduced once the equiaxed structure becomes predominant. An analysis of the microstructural parameters shows that the spacing between the boundaries is not affected

Fig. 9. Histogram showing the angle of misorientation across boundaries in a longitudinal section. (a) Strain 0.9; (b) Strain 30; (c) Strain 60.

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Fig. 10. Thin foil from a longitudinal section of a specimen deformed to a strain of 30. The misorientation angle (°) across a number of boundaries is marked.

In general, the microstructures observed at low and medium strain are significantly affected by deformation mechanism involving ordinary glide and localized deformation in S-bands and shear bands. At high strains there is no direct relationship between the morphology of the structure and the deformation mechanism, which now may involve such processes as sliding and coalescence of grain boundaries. However, the microstructures at all strains are typical Low Energy Dislocation Structures (LEDS) [17,20]. Observations supporting this statement are the checkerboard contrast observed in TEM micrographs and the increasing angle of misorientation for a constant spacing leading to a reduction in the energy per unit length of dislocation line [19]. At a large accumulated strain, many dislocation boundaries have been replaced by high angle boundaries in an equiaxed structure thereby reducing the total surface energy of these boundaries.

4.3. Microstructure and flow stress The analysis of the microstructure shows a clear subdivision by dislocation boundaries and high angle boundaries. The spacing between these boundaries is almost unaffected by the strain in the range examined. It is therefore suggested that the contribution of the deformation microstructure to the flow stress primarily depends on how the boundaries affect the slip length [21,22]. Here, it may be assumed that the resistance of a boundary depends primarily on the average density of dislocations in the boundary, which increases linearly with the angle of misorientation across the boundary [23]. A critical angle may therefore exist where the

resistance of a dislocation boundary equals that of a high angle grain boundary given by the Hall-Petch equation [23]. An increase in misorientation angle above such a critical angle should therefore not lead to an increase in the flow stress for a constant spacing. This tentative hypothesis is in good accord with the experimental observation, but further quantitative microscopy is required to underpin the hypothesis. 5. Conclusions Pure, polycrystalline aluminium has been deformed at room temperature in cyclic extrusion compression (CEC) to true strains in the range 0.9–60. The following can be concluded: The microstructure evolves from a cell block structure at lower strains into an equiaxed cell/subgrain structure at large strain. This structural transformation is assisted by localized glide and shear. Dynamic or static recrystallization structures have not been observed. The average misorientation angle across the boundaries subdividing the structure increases with the strain over the whole strain range leading to a distribution of angles, which shows a relatively high concentration of high angle boundaries (u\ 15°) at a strain of 60. The average spacing between the boundaries is practically unaffected by the strain. The flow stress increases with the accumulated strain to a saturation stress which is reached in the strain range 5–8. This evolution of flow stress as a function of the accumulated plastic strain is in good accord with the microstructural observations.

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Acknowledgements We thank H. Nilsson, J. Lindbo, P.B. Olesen for careful assistance with the experimental work with the microscopic analysis and Eva Sørensen for preparing the manuscript. We are also grateful for fruitful discussions with D.A. Hughes, D. Juul Jensen, A. Godfrey, O.B. Pedersen.

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