Conductive TiC/Ti–Cu/C composites fabricated by Ti–Cu alloy reactive infiltration into 3D-printed carbon performs

Abstract

The microstructure and electrical properties of dense TiC/Ti–Cu/C composites fabricated by pressureless reactive infiltration of Ti–Cu alloy into porous starch-derived carbon preforms prepared by 3D printing was evaluated. Porosities in the range of 65–78 vol% were varied by post-isostatic pressing the as-printed preforms at pressures of 50–400 MPa. The reactive melt infiltration was carried out at 1100℃ in a flowing Ar atmosphere and resulted in formation of a composite comprised predominantly of substoichiometric TiC, binary intermetallic Ti–Cu phases and residual carbon. Scanning electron microscopy analyses revealed a microstructure consisting of dispersed fine-grained TiC in a Ti–Cu matrix surrounded by a continuous carbon phase. Electrical resistivity measurements using the four-probe method were carried out and correlated to the composite microstructure. The electrical resistivity was evaluated in terms of carbon and TiC volume fractions.

Keywords

TiC/Ti–Cu/C composites Ti–Cu alloy 3D printing reactive infiltration

Get full access to this article

View all access options for this article.

References

Travitzky

Kumar

Sandhage

. Rapid synthesis of Al₂O₃ reinforced Fe-Cr-Ni composites. Mater Sci Eng A 2003; 344: 245–252.

Vasić

Grobéty

Kuebler

. Activation mechanism and infiltration kinetic for pressureless melt infiltration of Ti activated Al₂O₃ preforms by high melting alloy. Adv Eng Mater 2009; 11: 659–666.

Manna

Bains

Mahapatra

. Experimental study on fabrication of Al-Al₂O₃/Grp metal matrix composites. J Compos Mater 2011; 45: 2003–2010.

Kaftelen

Ünlü

Göller

. Comparative processing-structure-property studies of Al–Cu matrix composites reinforced with TiC particulates. Compos Part A Appl Sci 2011; 42: 812–824.

Stoloff

. Metals handbook 1990; Vol. 1, 10th ed. Metals Park, OH: ASM International, pp. 951–951.

Jenei

Gubicza

Yoon

. High temperature thermal stability of pure copper and copper–carbon nanotube composites consolidated by high pressure torsion. Compos Part A Appl Sci 2013; 51: 71–79.

Asthana

. Cast metal–matrix composites. II: process fundamentals. J Mater Synth Process 1997; 5: 339–339.

Weber

Theisen

. Sintering of high wear resistant metal matrix composites. Adv Eng Mater 2007; 9: 165–170.

Fahrenholtz

Ewsuk

Loehman

. Kinetics of ceramic-metal composite formation by reactive metal penetration. J Am Ceram Soc 1998; 81: 2533–2541.

10.

Travitzky

Gotman

Claussen

. Alumina-Ti aluminide interpenetrating composites: microstructure and mechanical properties. Mater Lett 2003; 57: 3422–3426.

11.

Wagner

Garcia

Krupp

. Interpenetrating Al₂O₃-TiAl₃ alloys produced by reactive infiltration. J Eur Ceram Soc 1999; 19: 2449–2453.

12.

Claussen

. Processing of advanced ceramic composites: issues of producibility, affordability, reliability, and tailorability. Br Ceram Trans 1999; 98: 256–257.

13.

Lyckfeldt

Ferreira

JMF

. Processing of porous ceramics by starch consolidation. J Eur Ceram Soc 1998; 18: 131–140.

14.

Rambo

Travitzky

Zimmermann

. Synthesis of TiC/Ti–Cu composites by pressureless reactive infiltration of TiCu alloy into carbon preforms fabricated by 3D-printing. Mater Lett 2005; 59: 1028–1031.

15.

Greil

. Near net shape manufacturing of ceramic. Mater Chem Phys 1999; 61: 64–68.

16.

Kumar

Kruth

J-P

. Composites by rapid prototyping technology. Mater Design 2010; 31: 850–856.

17.

Zhang

Travitzky

Greil

. Formation of NbAl₃/Al₂O₃ composites by pressureless reactive infiltration. J Am Ceram Soc 2008; 9: 3117–3120.

18.

Yin

Travitzky

Greil

. Near-net-shape fabrication of Ti₃AlC₂-based composites. Int J Appl Ceram Technol 2007; 4: 184–190.

19.

Melcher

Martins

Travitzky

. Fabrication of Al₂O₃-based composites by indirect 3D-printing. Mater Lett 2006; 60: 572–575.

20.

Wong

Fuh

JYH

. Effect of TiC in copper–tungsten electrodes on EDM performance. J Mater Process Technol 2001; 113: 563–567.

21.

Tsai

Yan

Huang

. EDM performance of Cr/Cu-based composite electrodes. Int J Mach Tools Manuf 2003; 43: 245–252.

22.

Zaw

Fuh

JYH

Nee

AYC

. Formation of a new EDM electrode material using sintering techniques. J Mater Process Technol 1999; 89–90: 182–186.

23.

Norasetthekul

Eubank

Bradley

. Use of zirconium diboride-copper as an electrode in plasma applications. J Mater Sci 1999; 34: 1261–1270.

24.

Pierson

. Handbook of refractory carbides and nitrides, Westwood, New Jersey, USA: Noyes Publications, 1996.

25.

Wong

Fuh

JYH

. EDM performance of TiC/copper-based sintered electrodes. Mater Des 2001; 22: 669–678.

26.

Dahan

Admon

Frage

. Diffusion in Ti/TiC multilayer coatings. Thin Solid Films 2000; 377–378: 687–693.

27.

Suzuki

Hirabayashi

Shibata

. Electrical and thermal conductivities in quenched and aged high-purity Cu–Ti alloys. Scripta Mater 2003; 48: 431–435.

28.

Sabatello

Frage

Dariel

. Graded TiC-based cermets. Mater Sci Eng A 2000; 288: 12–18.

29.

Lilly

Deevi

Gibbs

. Electrical properties of iron aluminides. Mater Sci Eng A 1998; 258: 42–49.

30.

Aldrich

Fan

Mummery

. Processing, microstructure and physical properties of interpenetrating Al₂O₃/Ni composites. Mater Sci Technol 2000; 16: 747–752.

31.

Chang

S-Y

Chen

C-F

Lin

S-J

. Electrical resistivity of metal matrix composites. Acta Mater 2003; 51: 6191–6302.