Shaw M C and Cookson J O 2005 Metal Cutting Principles (New York: Oxford University) |
Salomon C J 1931 Process for machining metals of similar acting materials when being worked by cutting tools German Patent 523594 |
Longbottom J M and Lanham J D 2006 A review of research related to Salomon’s hypothesis on cutting speeds and temperatures Int. J. Mach. Tools Manuf. 46 1740–7 |
Zener C and Hollomon J H 1944 Effect of strain rate upon plastic flow of steel J. Appl. Phys. 15 22–32 |
Wright T W and Batra R C 1985 The initiation and growth of adiabatic shear bands Int. J. Plast. 1 205–12 |
Davies M A, Burns T J and Evans C J 1997 On the dynamics of chip formation in machining hard metals CIRP Ann. 46 25–30 |
Burns T J and Davies M A 2002 On repeated adiabatic shear band formation during high-speed machining Int. J. Plast. 18 487–506 |
Ma W, Chen X and Shuang F 2017 The chip-flow behaviors and formation mechanisms in the orthogonal cutting process of Ti6Al4V alloy J. Mech. Phys. Solids 98 245–70 |
Ma W, Li X, Dai L and Ling Z 2012 Instability criterion of materials in combined stress states and its application to orthogonal cutting process Int. J. Plast. 30–31 18–40 |
Cai S L and Dai L H 2014 Suppression of repeated adiabatic shear banding by dynamic large strain extrusion machining J. Mech. Phys. Solids 73 84–102 |
Ye G G, Xue S F, Jiang M Q, Tong X H and Dai L H 2013 Modeling periodic adiabatic shear band evolution during high speed machining Ti-6Al-4V alloy Int. J. Plast. 40 39–55 |
Ye G G, Xue S F, Ma W, Jiang M Q, Ling Z, Tong X H and Dai L H 2012 Cutting AISI 1045 steel at very high speeds Int. J. Mach. Tools Manuf. 56 1–9 |
Gurrutxaga-Lerma B 2018 Adiabatic shear banding and the micromechanics of plastic flow in metals Int. J. Solids Struct. 132 153–70 |
Bai Y L 1982 Thermo-plastic instability in simple shear J. Mech. Phys. Solids 30 195–207 |
Recht R F 1964 Catastrophic thermoplastic shear J. Appl. Mech. 31 189–93 |
Ye G G, Jiang M Q, Xue S F, Ma W and Dai L H 2018 On the instability of chip flow in high-speed machining Mech. Mater. 116 104–19 |
Regazzoni G, Kocks U F and Follansbee P S 1987 Dislocation kinetics at high strain rates Acta Metall. 35 2865–75 |
Meyers M A 1994 Dynamic Behavior of Materials (New York: Wiley) |
Zerilli F J and Armstrong R W 1992 The effect of dislocation drag on the stress-strain behavior of F.C.C. metals Acta Metall. Mater. 40 1803–8 |
Follansbee P S and Kocks U F 1988 A constitutive description of the deformation of copper based on the use of the mechanical threshold stress as an internal state variable Acta Metall. 36 81–93 |
Parameswaran V R, Urabe N and Weertman J 1972 Dislocation mobility in aluminum J. Appl. Phys. 43 2982–6 |
Gurrutxaga-Lerma B, Balint D S, Dini D and Sutton A P 2015 The mechanisms governing the activation of dislocation sources in aluminum at different strain rates J. Mech. Phys. Solids 84 273–92 |
Gao C Y and Zhang L C 2012 Constitutive modelling of plasticity of fcc metals under extremely high strain rates Int. J. Plast. 32–33 121–33 |
Gurson A L 1977 Continuum theory of ductile rupture by void nucleation and growth: part I—yield criteria and flow rules for porous ductile media J. Eng. Mater. Technol. 99 2–15 |
Seaman L, Curran D R and Shockey D A 1976 Computational models for ductile and brittle fracture J. Appl. Phys. 47 4814–26 |
Tvergaard V and Needleman A 1984 Analysis of the cup-cone fracture in a round tensile bar Acta Metall. 32 157–69 |
Rudd R E and Belak J F 2002 Void nucleation and associated plasticity in dynamic fracture of polycrystalline copper: an atomistic simulation Comput. Mater. Sci. 24 148–53 |
Seppälä E T, Belak J and Rudd R E 2004 Effect of stress triaxiality on void growth in dynamic fracture of metals: a molecular dynamics study Phys. Rev. B 69 134101 |
Seppälä E T, Belak J and Rudd R E 2005 Three-dimensional molecular dynamics simulations of void coalescence during dynamic fracture of ductile metals Phys. Rev. B 71 064112 |
Sills R B and Boyce B L 2020 Void growth by dislocation adsorption Mater. Res. Lett. 8 103–9 |
Traiviratana S, Bringa E M, Benson D J and Meyers M A 2008 Void growth in metals: atomistic calculations Acta Mater. 56 3874–86 |
Nguyen L D and Warner D H 2012 Improbability of void growth in aluminum via dislocation nucleation under typical laboratory conditions Phys. Rev. Lett. 108 035501 |
Rice J R and Tracey D M 1969 On the ductile enlargement of voids in triaxial stress fields J. Mech. Phys. Solids 17 201–17 |
Huang Y 1991 Accurate dilatation rates for spherical voids in triaxial stress fields J. Appl. Mech. 58 1084–6 |
Hosseini S B, Klement U, Yao Y and Ryttberg K 2015 Formation mechanisms of white layers induced by hard turning of AISI 52100 steel Acta Mater. 89 258–67 |
Rogers H C 1979 Adiabatic plastic deformation Annu. Rev. Mater. Sci. 9 283–311 |
Meyers M A, Xu Y B, Xue Q, Pérez-Prado M T and McNelley T R 2003 Microstructural evolution in adiabatic shear localization in stainless steel Acta Mater. 51 1307–25 |
Duan C Z and Zhang L C 2012 Adiabatic shear banding in AISI 1045 steel during high speed machining: mechanisms of microstructural evolution Mater. Sci. Eng. A 532 111–9 |
Murr L E, Quinones S A, Ferreyra E, Ayala A, Valerio O L, Hörz F and Bernhard R P 1998 The low-velocity-to-hypervelocity penetration transition for impact craters in metal targets Mater. Sci. Eng. A 256 166–82 |
Murr L E, Trillo E A, Bujanda A A and Martinez N E 2002 Comparison of residual microstructures associated with impact craters in fcc stainless steel and bcc iron targets: the microtwin versus microband issue Acta Mater. 50 121–31 |
Murr L E and Esquivel E V 2004 Observations of common microstructural issues associated with dynamic deformation phenomena: twins, microbands, grain size effects, shear bands, and dynamic recrystallization J. Mater. Sci. 39 1153–68 |
Gao S, Wu Y, Kang R and Huang H 2018 Nanogrinding induced surface and deformation mechanism of single crystal β-Ga2O3 Mater. Sci. Semicond. Process. 79 165–70 |
Li C, Wu Y, Li X, Ma L, Zhang F and Huang H 2020 Deformation characteristics and surface generation modelling of crack-free grinding of GGG single crystals J. Mater. Process. Technol. 279 116577 |
Li C, Li X, Wu Y, Zhang F and Huang H 2019 Deformation mechanism and force modelling of the grinding of YAG single crystals Int. J. Mach. Tools Manuf. 143 23–37 |
Chou Y K and Evans C J 1999 White layers and thermal modeling of hard turned surfaces Int. J. Mach. Tools Manuf. 39 1863–81 |
Ramesh A, Melkote S N, Allard L F, Riester L and Watkins T R 2005 Analysis of white layers formed in hard turning of AISI 52100 steel Mater. Sci. Eng. A 390 88–97 |
Schulz H and Moriwaki T 1992 High-speed machining CIRP Ann. 41 637–43 |
Klocke F, Brinksmeier E, Evans C, Howes T, Lnasaki I, Minke E, Tönshoff H K, Webster J A and Stuff D 1997 High-speed grinding-fundamentals and state of the art in Europe, Japan, and the USA CIRP Ann. 46 715–24 |
Dudzinski D, Devillez A, Moufki A, Larrouquère D, Zerrouki V and Vigneau J 2004 A review of developments towards dry and high speed machining of Inconel 718 alloy Int. J. Mach. Tools Manuf. 44 439–56 |
Rahman M, Wang Z-G and Wong Y-S 2006 A review on high-speed machining of titanium alloys JSME Int. J. Ser. C 49 11–20 |
Yang X and Zhang B 2019 Material embrittlement in high strain-rate loading Int. J. Extrem. Manuf. 1 022003 |
Zhang T, Jiang F, Huang H, Lu J, Wu Y, Jiang Z and Xu X 2021 Towards understanding the brittle–ductile transition in the extreme manufacturing Int. J. Extrem. Manuf. 3 022001 |
Zhang B and Yin J 2019 The ‘skin effect’ of subsurface damage distribution in materials subjected to high-speed machining Int. J. Extrem. Manuf. 1 012007 |
Wang B, Liu Z, Cai Y, Luo X, Ma H, Song Q and Xiong Z 2021 Advancements in material removal mechanism and surface integrity of high speed metal cutting: a review Int. J. Mach. Tools Manuf. 166 103744 |
Molinari A, Soldani X and Miguélez M H 2013 Adiabatic shear banding and scaling laws in chip formation with application to cutting of Ti–6Al–4V J. Mech. Phys. Solids 61 2331–59 |
Hou X, Li J, Li Y and Tian Y 2022 Intermolecular and surface forces in atomic-scale manufacturing Int. J. Extrem. Manuf. 4 022002 |
Gao J, Luo X, Fang F and Sun J 2021 Fundamentals of atomic and close-to-atomic scale manufacturing: a review Int. J. Extrem. Manuf. 4 012001 |
Peierls R 1940 The size of a dislocation Proc. Phys. Soc. 52 34 |
Nabarro F R N 1947 Dislocations in a simple cubic lattice Proc. Phys. Soc. 59 256 |
Hull D and Bacon D J 2001 Introduction to Dislocations (Oxford: Butterworth-Heinemann) |
Messerschmidt U 2010 Dislocation Dynamics during Plastic Deformation (Heidelberg: Springer Science & Business Media) |
Wedberg D and Lindgren L-E 2015 Modelling flow stress of AISI 316L at high strain rates Mech. Mater. 91 194–207 |
Zerilli F J and Armstrong R W 1987 Dislocation-mechanicsbased constitutive relations for material dynamics calculations J. Appl. Phys. 61 1816–25 |
Hoge K G and Mukherjee A K 1977 The temperature and strain rate dependence of the flow stress of tantalum J. Mater. Sci. 12 1666–72 |
Steinberg D J and Lund C M 1989 A constitutive model for strain rates from 10−4 to 106 s−1 J. Appl. Phys. 65 1528–33 |
Taylor G I 1934 The mechanism of plastic deformation of crystals. Part I.—theoretical Proc. R. Soc. A 145 362–87 |
De Cooman B C, Estrin Y and Kim S K 2018 Twinning-induced plasticity (TWIP) steels Acta Mater. 142 283–362 |
Zaefferer S, Ohlert J and Bleck W 2004 A study of microstructure, transformation mechanisms and correlation between microstructure and mechanical properties of a low alloyed TRIP steel Acta Mater. 52 2765–78 |
Johnson G R and Cook W H 1985 Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressures Eng. Fract. Mech. 21 31–48 |
Klopp R W, Clifton R J and Shawki T G 1985 Pressure-shear impact and the dynamic viscoplastic response of metals Mech. Mater. 4 375–85 |
Gioia G and Ortiz M 1996 The two-dimensional structure of dynamic boundary layers and shear bands in thermoviscoplastic solids J. Mech. Phys. Solids 44 251–92 |
Molinari A and Clifton R J 1987 Analytical characterization of shear localization in thermoviscoplastic materials J. Appl. Mech. 54 806–12 |
Wright T W and Perzyna P 2003 Physics and mathematics of adiabatic shear bands Appl. Mech. Rev. 56 B41–B43 |
Oxley P L B and Shaw M C 1990 Mechanics of machining: an analytical approach to assessing machinability J. Appl. Mech. 57 253 |
Johnson W 1983 Impact Strength of Materials (London: Edward Arnold) |
Perzyna P 1986 Internal state variable description of dynamic fracture of ductile solids Int. J. Solids Struct. 22 797–818 |
Tonks D L, Vorthman J E, Hixson R, Kelly A and Zurek A K 2001 Spallation studies on shock loaded U-6 WT PCT NB AIP Conf. Proc. 505 329 |
Sui H, Yu L, Liu W, Liu Y, Cheng Y and Duan H 2021 Theoretical models of void nucleation and growth for ductile metals under dynamic loading: a review Matter Radiat. Extremes 7 018201 |
Lyles R L and Wilsdorf H G F 1975 Microcrack nucleation and fracture in silver crystals Acta Metall. 23 269–77 |
Cuitino A M and Ortiz M 1996 Ductile fracture by vacancy condensation in fcc single crystals Acta Mater. 44 427–36 |
Reina C, Marian J and Ortiz M 2011 Nanovoid nucleation by vacancy aggregation and vacancy-cluster coarsening in high-purity metallic single crystals Phys. Rev. B 84 104117 |
Seppälä E T, Belak J and Rudd R E 2004 Onset of void coalescence during dynamic fracture of ductile metals Phys. Rev. Lett. 93 245503 |
Marian J, Knap J and Ortiz M 2004 Nanovoid cavitation by dislocation emission in aluminum Phys. Rev. Lett. 93 165503 |
Marian J, Knap J and Ortiz M 2005 Nanovoid deformation in aluminum under simple shear Acta Mater. 53 2893–900 |
Krasnikov V S and Mayer A E 2015 Plasticity driven growth of nanovoids and strength of aluminum at high rate tension: molecular dynamics simulations and continuum modeling Int. J. Plast. 74 75–91 |
Irwin G J 1972 Metallographic Interpretation of Impacted Ogive Penetrators (Ottawa: Defence Research Board) |
Kumagai T, Izumi S, Hara S and Sakai S 2007 Development of bond-order potentials that can reproduce the elastic constants and melting point of silicon for classical molecular dynamics simulation Comput. Mater. Sci. 39 457–64 |
Zhao S, Hahn E N, Kad B, Remington B A, Wehrenberg C E, Bringa E M and Meyers M A 2016 Amorphization and nanocrystallization of silicon under shock compression Acta Mater. 103 519–33 |
Teng X, Wierzbicki T and Couque H 2007 On the transition from adiabatic shear banding to fracture Mech. Mater. 39 107–25 |
Grady D 2017 Physics of Shock and Impact vol 1 (Bristol: IOP Publishing) |
Rankine W J M 1998 On the thermodynamic theory of waves of finite longitudinal disturbance[Philos. Trans. 160 (1870), part II, 277–288] Classic Papers in Shock Compression Science, High-Press. Shock Compression Condens. Matter pp 133–47 |
Grüneisen E 1912 Theorie des festen Zustandes einatomiger Elemente Ann. Phys. 344 257–306 |
Anderson C E 1987 An overview of the theory of hydrocodes Int. J. Impact Eng. 5 33–59 |
Sutter G and List G 2013 Very high speed cutting of Ti–6Al–4V titanium alloy–change in morphology and mechanism of chip formation Int. J. Mach. Tools Manuf. 66 37–43 |
Sutter G 2005 Chip geometries during high-speed machining for orthogonal cutting conditions Int. J. Mach. Tools Manuf. 45 719–26 |
Sutter G, Faure L, Molinari A, Ranc N and Pina V 2003 An experimental technique for the measurement of temperature fields for the orthogonal cutting in high speed machining Int. J. Mach. Tools Manuf. 43 671–8 |
Zhou M, Rosakis A J and Ravichandran G 1996 Dynamically propagating shear bands in impact-loaded prenotched plates—I. Experimental investigations of temperature signatures and propagation speed J. Mech. Phys. Solids 44 981–1006 |
Timothy S P and Hutchings I M 1986 Adiabatic shear band fracture surfaces in a titanium alloy J. Mater. Sci. Lett. 5 453–4 |
Liao S and Duffy J 1998 Adiabatic shear bands in a TI-6Al-4V titanium alloy J. Mech. Phys. Solids 46 2201–31 |
Wang B, Sun J, Wang X and Fu A 2015 Adiabatic shear localization in a near beta Ti–5Al–5Mo–5 V–1Cr–1Fe alloy Mater. Sci. Eng. A 639 526–33 |
Wang B, Wang X, Li Z, Ma R, Zhao S, Xie F and Zhang X 2016 Shear localization and microstructure in coarse grained beta titanium alloy Mater. Sci. Eng. A 652 287–95 |
Xu Z, Junjia C and Guangyao L 2017 Microstructural mechanism in adiabatic shear bands of Al-Cu alloy bars using electromagnetic impact upsetting Mater. Lett. 194 62–65 |
Yang H, Zhang J H, Xu Y and Meyers M A 2008 Microstructural characterization of the shear bands in Fe-Cr-Ni single crystal by EBSD J. Mater. Sci. Technol. 24 819 |
Zou D L, Zhen L, Xu C Y and Shao W Z 2011 Characterization of adiabatic shear bands in AM60B magnesium alloy under ballistic impact Mater. Charact. 62 496–502 |
Kad B K, Gebert J-M, Perez-Prado M T, Kassner M E and Meyers M A 2006 Ultrafine-grain-sized zirconium by dynamic deformation Acta Mater. 54 4111–27 |
Peirs J, Tirry W, Amin-Ahmadi B, Coghe F, Verleysen P, Rabet L, Schryvers D and Degrieck J 2013 Microstructure of adiabatic shear bands in Ti6Al4V Mater. Charact. 75 79–92 |
Huang K and Logé R E 2016 A review of dynamic recrystallization phenomena in metallic materials Mater. Des. 111 548–74 |
Hines J A and Vecchio K S 1997 Recrystallization kinetics within adiabatic shear bands Acta Mater. 45 635–49 |
Meyers M A, Gregori F, Kad B K, Schneider M S, Kalantar D H, Remington B A, Ravichandran G, Boehly T and Wark J S 2003 Laser-induced shock compression of monocrystalline copper: characterization and analysis Acta Mater. 51 1211–28 |
Velásquez J D P, Bolle B, Chevrier P, Geandier G and Tidu A 2007 Metallurgical study on chips obtained by high speed machining of a Ti–6wt.%Al–4wt.%V alloy Mater. Sci. Eng. A 452–453 469–74 |
Derep J L 1987 Microstructure transformation induced by adiabatic shearing in armour steel Acta Metall. 35 1245–9 |
Duan C Z and Wang M J 2005 Characteristics of adiabatic shear bands in the orthogonal, cutting of 30CrNi3MoV steel J. Mater. Process. Technol. 168 102–6 |
Xu Y, Zhang J, Bai Y and Meyers M A 2008 Shear localization in dynamic deformation: microstructural evolution Metall. Mater. Trans. A 39 811–43 |
Li Z, Wang B, Zhao S, Valiev R Z, Vecchio K S and Meyers M A 2017 Dynamic deformation and failure of ultrafine-grained titanium Acta Mater. 125 210–8 |
Hosseini S B, Ryttberg K, Kaminski J and Klement U 2012 Characterization of the surface integrity induced by hard turning of bainitic and martensitic AISI 52100 steel Proc. CIRP 1 494–9 |
Österle W and Li P X 1997 Mechanical and thermal response of a nickel-base superalloy upon grinding with high removal rates Mater. Sci. Eng. A 238 357–66 |
Liao Z, Polyakov M, Diaz O G, Axinte D, Mohanty G, Maeder X, Michler J and Hardy M 2019 Grain refinement mechanism of nickel-based superalloy by severe plastic deformation—mechanical machining case Acta Mater. 180 2–14 |
Velásquez J D P, Tidu A, Bolle B, Chevrier P and Fundenberger J-J 2010 Sub-surface and surface analysis of high speed machined Ti–6Al–4V alloy Mater. Sci. Eng. A 527 2572–8 |
Xu X, Zhang J, Liu H, He Y and Zhao W 2019 Grain refinement mechanism under high strain-rate deformation in machined surface during high speed machining Ti6Al4V Mater. Sci. Eng. A 752 167–79 |
Bosheh S S and Mativenga P T 2006 White layer formation in hard turning of H13 tool steel at high cutting speeds using CBN tooling Int. J. Mach. Tools Manuf. 46 225–33 |
Herbert C, Axinte D A, Hardy M and Withers P 2014 Influence of surface anomalies following hole making operations on the fatigue performance for a nickel-based superalloy J. Manuf. Sci. Eng. 136 136–5 |
Zhou L, Shimizu J, Muroya A and Eda H 2003 Material removal mechanism beyond plastic wave propagation rate Precis. Eng. 27 109–16 |
Huang H and Liu Y C 2003 Experimental investigations of machining characteristics and removal mechanisms of advanced ceramics in high speed deep grinding Int. J. Mach. Tools Manuf. 43 811–23 |
Puttick K E, Whitmore L C, Chao C L and Gee A E 1994 Transmission electron microscopy of nanomachined silicon crystals Phil. Mag. A 69 91–103 |
Schinker M G 1991 Subsurface damage mechanisms at high-speed ductile machining of optical glasses Precis. Eng. 13 208–18 |
Goel S, Kovalchenko A, Stukowski A and Cross G 2016 Influence of microstructure on the cutting behaviour of silicon Acta Mater. 105 464–78 |
Liu C, Chen X, Ke J, She Z, Zhang J, Xiao J and Xu J 2021 Numerical investigation on subsurface damage in nanometric cutting of single-crystal silicon at elevated temperatures J. Manuf. Process. 68 1060–71 |
Zhang L and Zarudi I 2001 Towards a deeper understanding of plastic deformation in mono-crystalline silicon Int. J. Mech. Sci. 43 1985–96 |
Murr L E, Bujanda A A, Trillo E A and Martinez N E 2002 Deformation twins associated with impact craters in polycrystalline iron targets J. Mater. Sci. Lett. 21 559–63 |
Trillo E A, Esquivel E V, Murr L E and Magness L S 2002 Dynamic recrystallization-induced flow phenomena in tungsten–tantalum (4%)[001] single-crystal rod ballistic penetrators Mater. Charact. 48 407–21 |
Hahn E N, Germann T C, Ravelo R, Hammerberg J E and Meyers M A 2017 On the ultimate tensile strength of tantalum Acta Mater. 126 313–28 |
Meyers M A, Vöhringer O and Lubarda V A 2001 The onset of twinning in metals: a constitutive description Acta Mater. 49 4025–39 |
Johnston W G and Gilman J J 1959 Dislocation velocities, dislocation densities, and plastic flow in lithium fluoride crystals J. Appl. Phys. 30 129–44 |
Smith C S 1958 Metallographic studies of metals after explosive shock Trans. Met. Soc. AIME 212 |
Hornbogen E 1962 Shock-induced dislocations Acta Metall. 10 978–80 |
Meyers M A 1978 A mechanism for dislocation generation in shock-wave deformation Scr. Metall. 12 21–26 |
Armstrong R W, Arnold W and Zerilli F J 2007 Dislocation mechanics of shock-induced plasticity J. Metall. Mater. Trans. A 38 2605–10 |
Gurrutxaga-Lerma B, Balint D S, Dini D, Eakins D E and Sutton A P 2015 The role of homogeneous nucleation in planar dynamic discrete dislocation plasticity J. Appl. Mech. 82 82–7 |
Zhao S, Kad B, Hahn E N, Remington B A, Wehrenberg C E, Huntington C M, Park H-S, Bringa E M, More K L and Meyers M A 2015 Pressure and shear-induced amorphization of silicon Extreme Mech. Lett. 5 74–80 |
Zhao S, Kad B, Wehrenberg C E, Remington B A, Hahn E N, More K L and Meyers M A 2017 Generating gradient germanium nanostructures by shock-induced amorphization and crystallization Proc. Natl Acad. Sci. 114 9791–6 |
Zhao S, Flanagan R, Hahn E N, Kad B, Remington B A, Wehrenberg C E, Cauble R, More K and Meyers M A 2018 Shock-induced amorphization in silicon carbide Acta Mater. 158 206–13 |
Zhao S, Kad B, Remington B A, LaSalvia J C, Wehrenberg C E, Behler K D and Meyers M A 2016 Directional amorphization of boron carbide subjected to laser shock compression Proc. Natl Acad. Sci. 113 12088–93 |