[ad_1]
Kocks, U. F., Argon, A. S. & Ashby, M. F. Thermodynamics and kinetics of slip. Prog. Mater. Sci. 19, 1–291 (1975).
Ashby, M. F. A first report on deformation-mechanism maps. Acta Metall. 20, 887–897 (1972).
Zerilli, F. J. & Armstrong, R. W. Dislocation-mechanics-based constitutive relations for material dynamics calculations. J. Appl. Phys. 61, 1816–1825 (1987).
Sargent, P. M. & Ashby, M. F. The Presentation of High Strain-Rates on Deformation Mechanism Maps ADA128822 (Defense Technical Information Center, 1983).
Armstrong, R. W. & Li, Q. Dislocation mechanics of high-rate deformations. Metall. Mater. Trans. A 46, 4438–4453 (2015).
Meyers, M. A. & Chawla, K. K. Mechanical Metallurgy: Principles and Applications (Prentice-Hall, 1984).
Whelchel, R. L., Kennedy, G. B., Dwivedi, S. K., Sanders, T. H. & Thadhani, N. N. Spall behavior of rolled aluminum 5083-H116 plate. J. Appl. Phys. 113, 233506 (2013).
Liu, R., Salahshoor, M., Melkote, S. N. & Marusich, T. A unified material model including dislocation drag and its application to simulation of orthogonal cutting of OFHC Copper. J. Mater. Process. Technol. 216, 328–338 (2015).
Wulf, G. L. High strain rate compression of titanium and some titanium alloys. Int. J. Mech. Sci. 21, 713–718 (1979).
Armstrong, R. W. & Walley, S. M. High strain rate properties of metals and alloys. Int. Mater. Rev. 53, 105–128 (2008).
Abukhshim, N. A., Mativenga, P. T. & Sheikh, M. A. Heat generation and temperature prediction in metal cutting: a review and implications for high speed machining. Int. J. Mach. Tools Manuf. 46, 782–800 (2006).
Johnson, B. C., Minton, D. A., Melosh, H. J. & Zuber, M. T. Impact jetting as the origin of chondrules. Nature 517, 339–341 (2015).
Armstrong, R. W., Arnold, W. & Zerilli, F. J. Dislocation mechanics of copper and iron in high rate deformation tests. J. Appl. Phys. 105, 023511 (2009).
Follansbee, P. S. & Kocks, U. F. 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 (1988).
Kumar, A. & Kumble, R. G. Viscous drag on dislocations at high strain rates in copper. J. Appl. Phys. 40, 3475–3480 (1969).
Kanel, G. I., Fortov, V. E. & Razorenov, S. V. Shock-Wave Phenomena and the Properties of Condensed Matter (Springer, 2004).
Slikkerveer, P. J., Beuten, P. C. P., in’t Veld, F. H. & Schollen, H. Erosion and damage by sharp particles. Wear 217, 237–250 (1998).
Hassani-Gangaraj, M., Veysset, D., Nelson, K. A. & Schuh, C. A. Melt-driven erosion in microparticle impact. Nat. Commun. 9, 5077 (2018).
Assadi, H., Kreye, H., Gärtner, F. & Klassen, T. Cold spraying – a materials perspective. Acta Mater. 116, 382–407 (2016).
Sakino, K. Transition in rate controlling mechanism of FFC metals at very high strain rates and high temperatures. J. Phys. IV Fr. 10, 57–62 (2000).
Tang, Q. & Hassani, M. Quantifying dislocation drag at high strain rates with laser-induced microprojectile impact. Int. J. Plast. 175, 103924 (2024).
Nicholas, T. Tensile testing of materials at high rates of strain. Exp. Mech. 21, 177–185 (1981).
Curtis, A. D., Banishev, A. A., Shaw, W. L. & Dlott, D. D. Laser-driven flyer plates for shock compression science: launch and target impact probed by photon Doppler velocimetry. Rev. Sci. Instrum. 85, 043908 (2014).
Whelchel, R. L., Sanders, T. H. & Thadhani, N. N. Spall and dynamic yield behavior of an annealed aluminum–magnesium alloy. Scr. Mater. 92, 59–62 (2014).
Deschamps, J. et al. Additive laser excitation of giant nonlinear surface acoustic wave pulses. Phys. Rev. Appl. 20, 044044 (2022).
Hall, C. A. Isentropic compression experiments on the Sandia Z accelerator. Phys. Plasmas 7, 2069–2075 (2000).
Cenna, A. A., Page, N. W., Kisi, E. & Jones, M. G. Single particle impact tests using gas gun and analysis of high strain-rate impact events in ductile materials. Wear 271, 1497–1503 (2011).
Reiser, A. & Schuh, C. A. Microparticle impact testing at high precision, higher temperatures, and with lithographically patterned projectiles. Small Methods 7, e2201028 (2023).
Bertin, N., Carson, R., Bulatov, V. V., Lind, J. & Nelms, M. Crystal plasticity model of BCC metals from large-scale MD simulations. Acta Mater. 260, 119336 (2023).
Wu, C. Y., Li, L. Y. & Thornton, C. Energy dissipation during normal impact of elastic and elastic–plastic spheres. Int. J. Impact Eng. 32, 593–604 (2005).
Wu, C. Y., Li, L. Y. & Thornton, C. Rebound behaviour of spheres for plastic impacts. Int. J. Impact Eng. 28, 929–946 (2003).
Sun, Y., Veysset, D., Nelson, K. A. & Schuh, C. A. The transition from rebound to bonding in high-velocity metallic microparticle impacts: jetting-associated power-law divergence. J. Appl. Mech. 87, 091002 (2020).
Hassani, M., Veysset, D., Nelson, K. A. & Schuh, C. A. Material hardness at strain rates beyond 106 s−1 via high velocity microparticle impact indentation. Scr. Mater. 177, 198–202 (2020).
Yu, J., Wang, G. & Rong, Y. Experimental study on the surface integrity and chip formation in the micro cutting process. Procedia Manuf. 1, 655–662 (2015).
Whitney, D. in Comprehensive Hard Materials Vol. 2 (eds Sarin, V. K., Llanes, L. & Mari, D.) 491–505 (Elsevier, 2014).
Tabor, D. A simple theory of static and dynamic hardness. Proc. R. Soc. Lond. A. Math. Phys. Sci. 192, 247–274 (1948).
Totten, G. E. & Mackenzie, D. S. in ASM Handbook Vol. 4E, Heat Treating of Nonferrous Alloys 4E (ed. Totten, G. E.) 325–334 (ASM International, 2016).
Prime, M. B., Fensin, S. J., Jones, D. R., Dyer, J. W. & Martinez, D. T. Multiscale Richtmyer-Meshkov instability experiments to isolate the strain rate dependence of strength. Phys. Rev. E 109, 015002 (2024).
Akhondzadeh, S., Kang, M., Sills, R. B., Ramesh, K. T. & Cai, W. Direct comparison between experiments and dislocation dynamics simulations of high rate deformation of single crystal copper. Acta Mater. 250, 118851 (2023).
Chen, X., Xiong, L., McDowell, D. L. & Chen, Y. Effects of phonons on mobility of dislocations and dislocation arrays. Scr. Mater. 137, 22–26 (2017).
Tanner, A. B., McGinty, R. D. & McDowell, D. L. Modeling temperature and strain rate history effects in OFHC Cu. Int. J. Plast. 15, 575–603 (1999).
Mecking, H. & Kocks, U. F. Kinetics of flow and strain-hardening. Acta Metall. 29, 1865–1875 (1981).
Cai, W., Bulatov, V. V., Chang, J., Li, J. & Yip, S. in Dislocations in Solids Vol. 12 (eds Nabarro, F. R. N. & Hirth, J. P.) 1–80 (Elsevier, 2004).
Mohamed, F. A. & Langdon, T. G. The determination of the activation energy for superplastic flow. Phys. Status Solidi 33, 375–381 (1976).
Lea, L. J. & Jardine, A. P. Characterisation of high rate plasticity in the uniaxial deformation of high purity copper at elevated temperatures. Int. J. Plast. 102, 41–52 (2018).
Lea, L., Brown, L. & Jardine, A. Time limited self-organised criticality in the high rate deformation of face centred cubic metals. Commun. Mater. 1, 93 (2020).
Katagiri, K. et al. Transonic dislocation propagation in diamond. Science 382, 69–72 (2023).
Lee, J.-H., Loya, P. E., Lou, J. & Thomas, E. L. Dynamic mechanical behavior of multilayer graphene via supersonic projectile penetration. Science 346, 1092–1097 (2014).
Tiamiyu, A. A., Sun, Y., Nelson, K. A. & Schuh, C. A. Site-specific study of jetting, bonding, and local deformation during high-velocity metallic microparticle impact. Acta Mater. 202, 159–169 (2021).
Lienhard, J., Nelson, K. A. & Schuh, C. A. Melting and ejecta produced by high velocity microparticle impacts of steel on tin. J. Appl. Mech. 88, 111005 (2021).
[ad_2]
Source link
Leave a Reply