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Journal of Materials Science

Erschienen in:

03.01.2021 | Metals & corrosion

The defect evolution in 1-D shocked tantalum single crystals

verfasst von: B. Pang, I. P. Jones, J. C. F. Millett, G. Whiteman, Y.-L. Chiu

Erschienen in: Journal of Materials Science | Ausgabe 11/2021

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Abstract

Tantalum single crystals were impacted along [001], [011] and [111] using 1-D planar shock waves with pressures of 6.4 GPa, 15.4 GPa and 21.7 GPa. The defect structures generated have been characterised using scanning electron microscopy and transmission electron microscopy. Deformation twins were produced in the 15.4 GPa and 21.7 GPa shocked samples, but are not seen in the 6.4 GPa samples. The twinning types were found to be highly dependent on the orientation of the single crystals and to obey the Smith [18] model. The remaining shock-induced dislocation structure is largely random, presumably as a result of the release wave. The TEM observations also show evidence of surface relaxation.

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Florando JN, Barton NR, El-Dasher BS, McNaney JM, Kumar M (2013) Analysis of deformation twinning in tantalum single crystals under shock loading conditions. J Appl Phys 113:083522CrossRef

Gray GT, Vecchio KS (1995) Influence of peak pressure and temperature on the structure/property response of shock- loaded Ta and Ta-10W. Metall Mater Trans A 26:2555–2563CrossRef

Murr LE, Meyers MA, Niou C-S, Chen YJ, Pappu S, Kennedy C (1997) Shock-induced deformation twinning in tantalum. Acta Mater 45:157–175CrossRef

Hsiung LM, Lassila DH (2000) Shock-induced deformation twinning and omega transformation in tantalum and tantalum–tungsten alloys. Acta Mater 48:4851–4865CrossRef

G.T. Gray, V. Livescu, E.K. Cerreta, T.A. Mason, P.J. Maudlin, J.F. Bingert (2009). Influence of shockwave obliquity on deformation twin formation in Ta, in: DYMAT 2009 - 9th Int. Conf. Mech. Phys. Behav. Mater. under Dyn. Load., EDP Sciences, Les Ulis, France. pp. 963–969.

Gray GT, Bourne NK, Millett JCF (2003) Shock response of tantalum: lateral stress and shear strength through the front. J Appl Phys 94:6430–6436CrossRef

Reed BW, Reed Patterson J, Swift DC, Stolken JS, Minich RW, Kumar M (2011) A unified approach for extracting strength information from nonsimple compression waves part II experiment and comparison with simulation. J Appl Phys 110:113506CrossRef

Gray GT, Bourne NK, Livescu V, Trujillo CP, MacDonald S, Withers P (2014) The influence of shock-loading path on the spallation response of Ta. J Phys Conf Ser 500:112031CrossRef

Gray GT, Hull LM, Livescu V, Faulkner JR, Briggs ME, Cerreta EK (2012) Influence of sweeping detonation-wave loading on shock hardening and damage evolution during spallation loading in tantalum. EPJ Web Conf 26:02004CrossRef

10.

Pang B, Case S, Jones IP, Millett JCF, Whiteman G, Chiu YL, Bronkhorst CA (2018) The defect evolution in shock loaded tantalum single crystals. Acta Mater 148:482–491CrossRef

11.

Lu CH, Remington BA, Maddox BR, Kad B, Park HS, Prisbrey ST, Meyers MA (2012) Laser compression of monocrystalline tantalum. Acta Mater 60:6601–6620CrossRef

12.

Livescu V, Bingert JF, Mason TA (2012) Deformation twinning in explosively-driven tantalum. Mater Sci Eng A 556:155–163CrossRef

13.

Lu CH, Remington BA, Maddox BR, Kad B, Park HS, Kawasaki M, Langdon TG, Meyers MA (2013) Laser compression of nanocrystalline tantalum. Acta Mater 61:7767–7780CrossRef

14.

Chen CQ, Hu G, Florando JN, Kumar M, Hemker KJ, Ramesh KT (2013) Interplay of dislocation slip and deformation twinning in tantalum at high strain rates. Scr Mater 69:709–712CrossRef

15.

Ravelo R, Germann TC, Guerrero O, An Q, Holian BL (2013) Shock-induced plasticity in tantalum single crystals: interatomic potentials and large-scale molecular-dynamics simulations. Phys Rev B 88:134101CrossRef

16.

Tramontina D, Erhart P, Germann T, Hawreliak J, Higginbotham A, Park N, Ravelo R, Stukowski A, Suggit M, Tang Y, Wark J, Bringa E (2014) Molecular dynamics simulations of shock-induced plasticity in tantalum. High Energy Density Phys 10:9–15CrossRef

17.

Chen CQ, Florando JN, Kumar M, Ramesh KT, Hemker KJ (2014) Incipient deformation twinning in dynamically sheared bcc tantalum. Acta Mater 69:114–125CrossRef

18.

Smith CS (1958) Metallographic studies of metals after explosive shock. Trans Met Soc AIME. 212:574

19.

Schneider MS, Kad BK, Meyers MA, Gregori F, Kalantar D, Remington BA (2004) Laser-induced shock compression of copper: orientation and pressure decay effects. Metall Mater Trans A 35:2633–2646CrossRef

20.

Schneider MS, Kad B, Kalantar DH, Remington BA, Kenik E, Jarmakani H, Meyers MA (2005) Laser shock compression of copper and copper–aluminum alloys. Int J Impact Eng 32:473–507CrossRef

21.

Hornbogen E (1962) Shock-Induced Dislocations. Acta Metall 10:978–980CrossRef

22.

Meyers MA, Jarmakani H, Bringa EM, Remington BA (2009) Dislocations in Shock Compression and Release. Dislocations in Solids. Elsevier, NY, pp 91–197CrossRef

23.

Meyers MA (1978) A mechanism for dislocation generation in shock-wave deformation. Scr Metall 12:21–26CrossRef

24.

Leslie WC, Michalak JT, Aul FW (1963) Iron and Dilute Solid Solutions. Wiley, New York

25.

L.L. Hsiung (2006). On the Micromechanisms of Shock-Induced Martensitic Transformation in Tantalum. In: AIP Conf. Proc., AIP. pp. 228–231.

26.

Higgins DL, Pang B, Millett JCF, Whiteman G, Jones IP, Chiu YL (2015) Contrasting the microstructural and mechanical response to shock loading of cold-rolled copper with annealed copper. Metall Mater Trans A 46:4518–4521CrossRef

27.

Millett JCF, Higgins DL, Chapman DJ, Whiteman G, Jones IP, Chiu Y-L (2018) The effects of prior cold work on the shock response of copper. J Dyn Behav Mater 4:211–221CrossRef

28.

Gray GT (1990) Shock recovery experiments: an assessment. In: Schmidt SC, Johnson JN, Davison LW (eds) Shock Compression of Condensed Matter-1989. North-Holland, Amsterdam, pp. 407–414.

29.

Gray GT (1991) Deformation substructures induced by high-rate deformation. In: Lowe TC, Rollett AD, Follansbee PS, Daehn GS (eds) Modelling the deformation of crystalline solids. The minerals, metals and materials society. pp. 145–158.

30.

Gray GT (1991) Influence of shock wave deformation on the structure/property behaviour of materials. In: Asay JR, Shahinpoor M (eds) High-Pressure Shock Compression of Solids. Springer, New York. pp. 187–215

31.

Gray GT (1992) Shock experiments in metals and ceramics. In: Meyers MA, Murr LE, Staudhammer KP (eds) Materials. Marcel Dekker, New York, pp 899–911

32.

N. Bourne, G.T. Gray (2005), Computational design of recovery experiments for ductile metals, Proc. R. Soc. A Math. Phys. Eng. Sci. 461: 3297–3312

33.

Loretto MH, Smallman RE (1975) Defect analysis in electron microscopy. Springer, US

34.

Gray GT, Follansbee PS, Frantz CE (1989) Effect of residual strain on the substructure development and mechanical response of shock-loaded copper. Mater Sci Eng A 111:9–16CrossRef

35.

Asay JR (2012) High-Pressure Shock Compression of Solids. Springer, New York

36.

Gillis PP, Hoge KG, Wasley RJ (1971) Elastic Precursor Decay in Tantalum. J Appl Phys 42:2145–2146CrossRef

37.

Taylor JW (1965) Dislocation Dynamics and Dynamic Yielding. J Appl Phys 36:3146–3150CrossRef

38.

Rohde RW (1973) Metallurgical Effects at High Strain Rates. Springer, US, Boston, MACrossRef

39.

Sencer BH, Maloy SA, Gray GT (2005) The influence of shock-pulse shape on the structure/property behavior of copper and 316 L austenitic stainless steel. Acta Mater 53:3293–3303CrossRef

40.

Davison L, Shahinpoor M (1998) High-Pressure Shock Compression of Solids III. Springer, New YorkCrossRef

41.

Wongwiwat K, Murr LE (1978) Effect of shock pressure, pulse duration, and grain size on shock-deformation twinning in molybdenum. Mater Sci Eng 35:273–285CrossRef

42.

Zeng ZH, Li XZ, Li C, Lu L, Zhang H, Luo SN (2019) Deformation twinning in a mild steel: loading dependence and strengthening. Mater Sci Eng A 751:332–339CrossRef

43.

Hahn EN, Fensin SJ, Germann TC, Gray GT (2018) Orientation dependent spall strength of tantalum single crystals. Acta Mater 159:241–248CrossRef

44.

Hahn EN, Germann TC, Ravelo R, Hammerberg JE, Meyers MA (2017) On the ultimate tensile strength of tantalum. Acta Mater 126:313–328CrossRef

45.

Meyers MA (1994) Dynamic Behaviour of Materials. Wiley, NY., p 116CrossRef

46.

Pang B, Jones I, Chiu Y, Millett J, Whiteman G, Bourne N (2014) Orientation dependence of shock induced dislocations in tantalum single crystals. J Phys Conf Ser 522:012029CrossRef

47.

Whiteman G, Case S, Millett JCF (2014) Planar shock compression of single crystal tantalum from 6–23 GPa. J Phys Conf Ser 500:112067CrossRef

Titel: The defect evolution in 1-D shocked tantalum single crystals
verfasst von: B. Pang
I. P. Jones
J. C. F. Millett
G. Whiteman
Y.-L. Chiu
Publikationsdatum: 03.01.2021
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 11/2021
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-020-05679-z

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