Method for controlling flow localization in machining processes

The invention claimed is: 1. A process of producing a machined component from a material, the process comprising the steps of: conducting a first machining operation without a constraining member to produce a first chip from a solid body of the material and to form a first machined surface on the material by providing relative motion between the material and a cutting edge of a cutting member, the first machining operation causing flow localization that creates a serrated flow pattern within the first chip; microscopically examining the first chip to detect the serrated flow pattern and measure by optical microscopy a maximum chip thickness of the first chip within the serrated flow pattern and a minimum chip thickness of the first chip within the serrated flow pattern; conducting a second machining operation with a constraining member to continuously produce a second chip from the solid body of the material and to form from the solid body the machined component having a second machined surface on the material by providing relative motion between the material and the cutting edge of the cutting member; simultaneously extruding the second chip in the immediate vicinity of the cutting edge and as the second chip is separated from the material by the cutting edge to continuously plastically deform the second chip and produce an extruded chip, the extruding step being performed at least in part by the constraining member that defines an opening with the cutting edge of the cutting member and through which the second chip passes and is plastically deformed to produce the extruded chip, a spacing being defined between an edge of the constraining member and the cutting edge of the cutting member; wherein the second machining operation comprises adjusting the spacing between the cutting edge of the cutting member and the edge of the constraining member such that the extruded chip has an extruded chip thickness that is less than or equal to the minimum chip thickness of the first chip; and wherein the extruded chip has a cross-sectional shape having two orthogonal dimensions comprising a thickness dimension determined by the extruded chip thickness and a width dimension orthogonal to the thickness dimension, the extruded chip having a microstructure in which flow localization in the extruded chip is suppressed to a level relative to the flow localization caused by the first machining operation so as to result in the second machined surface of the machined component formed by the second machining operation exhibiting lower heterogeneity in deformation and higher surface smoothness relative to the first machined surface formed on the material by the first machining operation. 2. The process according to claim 1 , wherein the second chip is continuously produced to have a nanostructured microstructure and the microstructure of the extruded chip is nanostructured. 3. The process according to claim 1 , wherein the constraining member comprises a die through which the second chip is forced as a result of being continuously produced. 4. The process according to claim 1 , wherein the cutting edge is stationary and the material moves relative to the cutting edge during the continuous producing step. 5. The process according to claim 1 , wherein the material rotates during the continuous producing and extruding steps. 6. The process according to claim 1 , wherein the material is stationary and the cutting edge moves relative to the material during the continuous producing step. 7. The process according to claim 1 , wherein the extruding step induces a change in each of the two orthogonal dimensions. 8. The process according to claim 1 , wherein the extruded chip has a round or rectilinear cross-sectional shape. 9. The process according to claim 1 , wherein the serrated flow pattern comprises shear banding in the first chip. 10. The process according to claim 9 , wherein the material is a low thermal diffusivity metal alloy. 11. The process according to claim 1 , wherein the serrated flow pattern comprises segmentation in the first chip. 12. The process according to claim 11 , wherein the material is a partially hardened metal alloy. 13. The process according to claim 1 , wherein the material is an annealed metal alloy. 14. The process according to claim 1 , wherein the material is chosen from the group consisting of metallic, intermetallic, composites, and ceramic materials, such that the extruded chip is entirely formed of the material. 15. The machined component produced by the process of claim 1 and having the second machined surface on the material. 16. The process according to claim 1 , further comprising performing on the machined component at least one treatment chosen from the group consisting of thermal treatments, mechanical treatments, and thermo-mechanical treatments. 17. A process of producing a machined component from a material, the process comprising the steps of: conducting a first machining operation without a constraining member to produce a first chip from a solid body of the material and to form a first machined surface on the material by providing relative motion between the material and a cutting edge of a cutting member, the first machining operation causing flow localization that creates a serrated flow pattern within the first chip; microscopically examining the first chip to detect the serrated flow pattern and measure by optical microscopy a maximum chip thickness of the first chip within the serrated flow pattern and a minimum chip thickness of the first chip within the serrated flow pattern; determining an average chip thickness of the first chip; conducting a second machining operation with a constraining member to continuously produce a second chip from the solid body of the material and to form from the solid body the machined component having a second machined surface on the material by providing relative motion between the material and the cutting edge of the cutting member; and simultaneously extruding the second chip in the immediate vicinity of the cutting edge and as the second chip is separated from the material by the cutting edge to continuously plastically deform the second chip and produce an extruded chip, the extruding step being performed at least in part by the constraining member that defines an opening with the cutting edge of the cutting member and through which the second chip passes and is plastically deformed to produce the extruded chip, a spacing being defined between an edge of the constraining member and the cutting edge of the cutting member; wherein the second machining operation comprises adjusting the spacing between the cutting edge of the cutting member and the edge of the constraining member such that the extruded chip has an extruded chip thickness that is less than or equal to the average chip thickness of the first chip; and wherein the extruded chip has a cross-sectional shape having two orthogonal dimensions comprising a thickness dimension determined by the extruded chip thickness and a width dimension orthogonal to the thickness dimension, the extruded chip having a microstructure in which flow localization in the extruded chip is suppressed to a level relative to the flow localization caused by the first machining operation so as to result in the second machined surface of the machined component formed by the second machining operation exhibiting lower heterogeneity in deformation and higher surface smoothness relative to the first machined surface formed on the material by the first machining operation.