The evolution of microstructures and texture subjected to a burnishing process in pure copper was investigated by transmission electron microscopy and electron backscattered diffraction. The grains of the top surface underwent significant refinement with a minimum grain size of ∼100 nm. The grain refinement was dominated by dislocation activities, including formation of dislocation cells, transformation of cell walls into sub-grain boundaries, development of highly disoriented sub-boundaries and generation of equiaxed grains. Shear strain induced by friction affected the strain state at the first pass of burnishing, resulting in a {001}<110> shear texture. Brass orientation developed well at the early stage of burnishing. Then, with a further increase in plastic strain, Brass orientation decreased, while the Goss orientation was observed, which mainly owing to the transformation from Brass to Goss orientation by rotation along the α-fibre. Moreover, dynamic recrystallisation occurred as the strain increased.
El-AxirMH: ‘An investigation into roller burnishing’, Int. J. Mach. Tool. Manuf., 2000, 40, 1603–1617.
2.
ZhangP, LindemannJ, DingWJ and LeyensC: ‘Effect of roller burnishing on fatigue properties of the hot-rolled Mg–12Gd–3Y magnesium alloy’, Mater. Chem. Phys., 2010, 124, 835–840.
3.
PrevéyPS and CammettJT: ‘The influence of surface enhancement by low plasticity burnishing on the corrosion fatigue performance of AA7075-T6’, Int. J. Fatigue, 2004, 26, 975–982.
4.
HassanAM. Al-JalilHF and EbiedAA: ‘Burnishing force and number of ball passes for the optimum surface finish of brass components’, J. Mater. Process. Technol., 1998, 83, 176–179.
5.
El-AxirMH and IbrahimAA: ‘Some surface characteristics due to center rest ball burnishing’, J. Mater. Process. Technol., 2005, 167, 47–53.
6.
GrzesikW and ŻakK: ‘Modification of surface finish produced by hard turning using superfinishing and burnishing operations’, J. Mater. Process. Technol., 2012, 212, 315–322.
7.
ZhangP, LindemannJ, DingWJ and LeyensC: ‘Effect of roller burnishing on fatigue properties of the hot-rolled Mg–12Gd–3Y magnesium alloy’, Mater. Chem. Phys., 2010, 124, 835–840.
8.
ZhangJX and JiangYY: ‘Fatigue of polycrystalline copper with different grain sizes and texture’, Int. J. Plast., 2006, 22, 536–556.
9.
PuZ, YangS, SongG.-L, DillonOWJr, PuleoDA and JawahirIS: ‘Ultrafine-grained surface layer on Mg–Al–Zn alloy produced by cryogenic burnishing for enhanced corrosion resistance’, Scr. Mater., 2011, 65, 520–523.
10.
ZhangP and LindemannJ: ‘Effect of roller burnishing on the high cycle fatigue performance of the high-strength wrought magnesium alloy AZ80’, Scr. Mater., 2005, 52, 1011–1015.
11.
NallaRK, AltenbergerI, NosterU, LiuGY, ScholtesB and RitchieRO: ‘On the influence of mechanical surface treatments deep rolling and laser shock peening on the fatigue behavior of Ti 6Al 4V at ambient and elevated temperatures’, Mater. Sci. Eng. A, 2003, A355, 216–230.
12.
ZouJ, LuoHY, HanZY and LvJL: ‘Investigation of texture characteristics of deformed layers in burnished 2024 aluminum alloy subsurface by EBSD’, Nanosci. Nanotechnol. Lett., 2013, 5, 1–8.
13.
LvJL, LuoHY and XieJP: ‘Experimental study of corrosion behavior for burnished aluminum alloy by EWF, EBSD, EIS and Raman spectra’, Appl. Surf. Sci., 2013, 273, 192–198.
14.
WangK, TaoNR, LiuG, LuJ and LuK: ‘Plastic strain-induced grain refinement at the nanometer scale in copper’, Acta Mater., 2006, 54, 5281–5291.
15.
ZhuKY, VasselA, BrissetF, LuK and LuJ: ‘Nanostructure formation mechanism of α-titanium using SMAT’, Acta Mater., 2004, 52, 4101–4110.
16.
LiD, ChenHN and XuH: ‘The effect of nanostructured surface layer on the fatigue behaviors of a carbon steel’, Appl. Surf. Sci., 2009, 255, 3811–3816.
17.
BonnotE, HelbertA.-L, BrissetF and BaudinT: ‘Microstructure and texture evolution during the ultra grain refinement of the Armco iron deformed by accumulative roll bonding (ARB)’, Mater. Sci. Eng. A, 2013, A561, 60–66.
18.
Palit SagarS, Ravi KumarB, Ghosh ChowdhuryS, DePK and GhoshRN: ‘Determination of crystallographic texture in cold-rolled copper and stainless steel by spectrum analysis of ultrasonic signal’, Scr. Mater., 2008, 58, 595–598.
19.
ChenLW, ShiQN, ChenDQ, ZhouSP, WangJL and LuoXM: ‘Research of textures of ultrafine grains pure copper produced by accumulative roll-bonding’, Mater. Sci. Eng. A, 2009, A508, 37–42.
20.
BelyakovA, SakaiT, MiuraH and TsuzakiK: ‘Grain refinement in copper under large strain deformation’, Philos. Mag. A, 2001, 81A, 2629–2643.
21.
Dalla TorreF, LapovokR, SandlinJ, ThomsonPF, DaviesCHJ and PerelomaEV: ‘Microstructures and properties of copper processed by equal channel angular extrusion for 1–16 passes’, Acta Mater., 2004, 52, 4819–4832.
22.
MishraA, KadBK, GregoriF and MeyersMA: ‘Microstructural evolution in copper subjected to severe plastic deformation: experiments and analysis’, Acta Mater., 2007, 55, 13–28.
23.
XuC, FurukawaM, HoritaZ and LangdonTG: ‘Using ECAP to achieve grain refinement, precipitate fragmentation and high strain rate superplasticity in a spray-cast aluminum alloy’. Acta Mater., 2003, 51, 6139–6148.
24.
MishraA, RichardV, GregoriF, KadB, AsaroRJ and MeyersMA: ‘Effect of initial grain size, die angle and pass sequence on the formation of ultrafine grain structure in Cu by ECAP’, Mater. Sci. Forum, 2006, 503–504, 25–30.
25.
AnXH, LinQY, WuSD and ZhangZF: ‘Mechanically driven annealing twinning induced by cyclic deformation in nanocrystalline Cu’, Scr. Mater., 2013, 68, 988–991.
26.
QuS, AnXH, YangHJ, HuangCX, YangG, ZangQS, WangZG, WuSD and ZhangZF: ‘Microstructural evolution and mechanical properties of Cu–Al alloys subjected to equal channel angular pressing’, Acta Mater., 2009, 57, 1586–1601.
27.
KhaledJ and Al-Fadhalah: ‘Texture and grain boundary character distribution in a thermomechanically processed OFHC copper’, J. Eng. Mater. Technol., 2012, 134, 1–9.
28.
LuoHY, LiuJY, WangLJ and ZhongQP: ‘Study of the mechanism of the burnishing process with cylindrical polycrystalline diamond tools’, J. Mater. Process. Technol., 2006, 180, 9–16.
29.
SidorJJ, PetrovRH and KestensLAI: ‘Microstructural and texture changes in severely deformed aluminum alloys’, Mater. Charact., 2011, 62, 228–236.
30.
WangSC, StarinkMJ, GaoN, QiaoXG, XuC and LangdonTG: ‘Texture evolution by shear on two planes during ECAP of a high-strength aluminum’, Acta Mater., 2008, 56, 3800–3809.
