Various methods for the production of bulk nanostructured (NS)/ultrafine-grained (UFG) materials have been developed, including equal channel angular extrusion (ECAE), a form of severe plastic deformation. Using an ECAE NS/UFG copper bar as an example, this study has investigated machining-induced workpiece microstructure variation using X-ray diffraction. It has been found that (1) under gentle cutting conditions, there was a 10% increase in the median grain size compared with unmachined ECAE NS/UFG copper bars. Increases in the arithmetic-, area-, and volume-weighted grain sizes were found to be 10%, 8%, and 8%, respectively, and (2) an average 27% drop in the dislocation density was observed between the machined and unmachined ECAE copper bars. The dislocation density was shown to have the most reduction at the outer radius of the machined ECAE bar where more heat and/or higher pressure were experienced.
Issue Section:
Research Papers
1.
Baro
, M. D.
, Kolobov
, Y. R.
, Ovidko
, I. A.
, Schaefer
, H. E.
, Straumal
, B. B.
, Valiev
, R. Z.
, Alexandrov
, I. V.
, Ivanov
, M.
, Reimann
, K.
, Reizis
, A. B.
, Surinach
, S.
, and Zhilyaev
, A. P.
, 2001, “Diffusion and Related Phenomena in Bulk Nanostructured Materials
,” Rev. Adv. Mater. Sci.
1606-5131, 2
, pp. 1
–43
.2.
Lowe
, T.
, 2006, “Metals and Alloys Nanostructured by Severe Plastic Deformation: Commercialization Pathways
,” JOM
1047-4838, 58
(4
), pp. 28
–32
.3.
Valiev
, R. Z.
, Islamgaliev
, R. K.
, and Alexandrov
, I. V.
, 2000, “Bulk Nanostructured Materials From Severe Plastic Deformation
,” Prog. Mater. Sci.
0079-6425, 45
, pp. 103
–189
.4.
Fukuda
, Y.
, Oh-ishi
, K.
, Horita
, Z.
, and Langdon
, T. G.
, 2002, “Processing of a Low-Carbon Steel by Equal-Channel Angular Pressing
,” Acta Mater.
1359-6454, 50
, pp. 1359
–1368
.5.
Haouaoui
, M.
, Karaman
, I.
, Maier
, H. J.
, and Hatwig
, K. T.
, 2004, “Microstructure Evolution and Mechanical Behavior of Bulk Copper Obtained by Consolidation of Micro- and Nanopowders Using Equal Channel Angular Extrusion
,” Metall. Mater. Trans. A
1073-5623, 35
, pp. 2935
–2949
.6.
Furukawa
, M.
, Horita
, Z.
, Nemoto
, M.
, and Langdon
, T. G.
, 2001, “Review Processing of Metals by Equal-Channel Angular Pressing
,” J. Mater. Sci.
0022-2461, 36
, pp. 2835
–2843
.7.
Morehead
, M.
, Huang
, Y.
, Zhu
, Y. T.
, Lowe
, T. C.
, and Valiev
, R. Z.
, 2006, “Experimental Investigation of the Machinability of Equal Channel Angular Pressing Processed Commercially Pure Titanium
,” Trans. NAMRI/SME
1047-3025, 34
, pp. 539
–546
.8.
Morehead
, M.
, Huang
, Y.
, and Hartwig
, K. T.
, 2007, “Machinability of Ultrafine-Grained Copper Using Tungsten Carbide and Polycrystalline Diamond Tools
,” Int. J. Mach. Tools Manuf.
0890-6955, 47
(2
), pp. 286
–293
.9.
Valiev
, R. Z.
, 1997, “Structure and Mechanical Properties of Ultrafine-Grained Metals
,” Mater. Sci. Eng., A
0921-5093, 234–236
, pp. 59
–66
.10.
2004, Kennametal Lathe Tooling, Catalog 1010, Latrobe, PA.
11.
Ungár
, T.
, Gubicza
, J.
, Ribarik
, G.
, and Borbely
, A.
, 2001, “Crystallite Size Distribution and Dislocation Structure Determined by Diffraction Profile Analysis: Principles and Practical Application to Cubic and Hexagonal Crystals
,” J. Appl. Crystallogr.
0021-8898, 34
, pp. 298
–310
.12.
Gubicza
, J.
, Balogh
, L.
, Hellmig
, R. J.
, Estrin
, Y.
, and Ungar
, T.
, 2005, “Dislocation Structure and Crystallite Size in Severely Deformed Copper by X-Ray Peak Profile Analysis
,” Mater. Sci. Eng., A
0921-5093, 400–401
, pp. 334
–338
.13.
Ungár
, T.
, 2003, “The Meaning of Size Obtained From Broadened X-Ray Diffraction Peaks
,” Adv. Eng. Mater.
1438-1656, 5
, pp. 323
–329
.14.
Warren
, B. E.
, and Averbach
, B. L.
, 1950, “The Effect of Cold-Work Distortion on X-Ray Patterns
,” J. Appl. Phys.
0021-8979, 21
, pp. 595
–599
.15.
Williamson
, G. K.
, and Hall
, W. H.
, 1953, “X-Ray Line Broadening From Filled Aluminum and Wolfram
,” Acta Metall.
0001-6160, 1
, pp. 22
–31
.16.
Gubicza
, J.
, Ribarik
, G.
, Goren-Munginstein
, G. R.
, Rosen
, A. R.
, and Ungar
, T.
, 2001, “The Density and the Character of Dislocations in Cubic and Hexagonal Polycrystals Determined by X-Ray Diffraction
,” Mater. Sci. Eng., A
0921-5093, 309–310
, pp. 60
–63
.17.
Gubicza
, J.
, Dragomir
, I. C.
, Ribarik
, G.
, Zhu
, Y. T.
, Valiev
, R.
, and Ungar
, T.
, 2003, “Characterizations of the Microstructure of Severely Deformed Titanium by X-Ray Diffraction Profile Analysis
,” Mater. Sci. Forum
0255-5476, 414–415
, pp. 229
–234
.18.
Scardi
, P.
, Leoni
, M.
, and Delhez
, R.
, 2004, “Line Broadening Analysis Using Integral Breadth Methods: A Critical Review
,” J. Appl. Crystallogr.
0021-8898, 37
, pp. 381
–390
.19.
Ribárik
, G.
, Ungár
, T.
, and Gubicza
, J.
, 2001, “MWP-Fit: A Program for Multiple Whole-Profile Fitting of Diffraction Peak Profiles by Ab Initio Theoretical Functions
,” J. Appl. Crystallogr.
0021-8898, 34
, pp. 669
–676
.20.
Kril
, C. E.
, and Birringer
, R.
, 1998, “Estimating Grain-Size Distributions in Nanocrystalline Materials From X-Ray Diffraction Profile Analysis
,” Philos. Mag. A
0141-8610, 77
, pp. 621
–640
.21.
Ungar
, T.
, Borbely
, A.
, Goren-Muginstein
, G. R.
, Berger
, S.
, and Rosen
, A. R.
, 1999, “Particle-Size, Size Distribution and Dislocations in Nanocrystalline Tungsten-Carbide
,” Nanostructured Materials
, 11
, pp. 103
–113
.22.
Gubicza
, J.
, Szepvolgyi
, J.
, Mohai
, I.
, Zsoldos
, L.
, and Ungar
, T.
, 2000, “Particle Size Distribution and Dislocation Density Determined by High Resolution X-Ray Diffraction in Nanocrystalline Silicon Nitride Powders
,” Mater. Sci. Eng., A
0921-5093, 280
, pp. 263
–269
.23.
Gubicza
, J.
, Nam
, N. H.
, Balogh
, L.
, Hellmig
, R. J.
, Stolyarov
, V. V.
, Estrin
, Y.
, and Ungar
, T.
, 2004, “Microstructure of Severely Deformed Metals Determined by X-Ray Peak Profile Analysis
,” J. Alloys Compd.
0925-8388, 378
, pp. 248
–252
.24.
Hinds
, W. C.
, 1982, Aerosol Technology: Properties, Behavior, and Measurement of Airborne Particles
, Wiley
, New York
.25.
Ungar
, T.
, 2004, “Microstructural Parameters From X-Ray Diffraction Peak Broadening
,” Scr. Mater.
1359-6462, 51
, pp. 777
–781
.26.
Zhu
, Y. T.
, Huang
, J. Y.
, Gubicza
, J.
, Ungar
, T.
, Wang
, Y. M.
, Ma
, E.
, and Valiev
, R. Z.
, 2003, “Nanostructures in Ti Processed by Severe Plastic Deformation
,” J. Mater. Res.
0884-2914, 18
, pp. 1908
–1917
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