Fully reversible, dislocation-based compressive deformation of Ti3SiC2 to 1 GPa

Barsoum, Michel W.; Zhen, T.; Kalidindi, Surya R.; Radović, Miladin; Murugaiah, A.

doi:10.1038/nmat814

Cited by 347 publications

(248 citation statements)

References 22 publications

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“…Other unexplored properties include superconductivity and magnetism. For mechanical properties, Barsoum's "incipient kink band" model [302] requires testing by, for example, in-situ nanoindentation in a TEM.…”

Section: Discussionmentioning

confidence: 99%

The M+1AX phases: Materials science and thin-film processing

et al. 2010

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This article is a critical review of the M n+1 AX n phases ("MAX phases", where n =1, 2, or 3) from a materials science perspective. MAX phases are a class of hexagonal-structure ternary carbides and nitrides ("X") of a transition metal ("M") and an A-group element. The most well known are Ti 2 AlC, Ti 3 SiC 2 , and Ti 4 AlN 3 . There are ~60 MAX phases with at least 9 discovered in the last five years alone. What makes the MAX phases fascinating and potentially useful is their remarkable combination of chemical, physical, electrical, and mechanical properties, which in many ways combine the characteristics of metals and ceramics. For example, MAX phases are typically resistant to oxidation and corrosion, elastically stiff, but at the same time they exhibit high thermal and electrical conductivities and are machinable. These properties stem from an inherently nanolaminated crystal structure, with M n+1 X n slabs intercalated with pure A-element layers. The research on MAX phases has been accelerated by the introduction of thin-film processing methods.Magnetron sputtering and arc deposition have been employed to synthesize single-crystal material by epitaxial growth, which enables studies of fundamental materials properties. However, the surface-initiated decomposition of M n+1 AX n thin films into MX compounds at temperatures of 1000-1100 °C is much lower than the decomposition temperatures typically reported for the corresponding bulk material. We also review the prospects for low-temperature synthesis, which is essential for deposition of MAX phases onto technologically important substrates. While deposition of MAX phases from the archetypical Ti-Si-C and Ti-Al-N systems typically require synthesis temperatures of ~800 °C, recent results have demonstrated that V 2 GeC and Cr 2 AlC can be deposited at ~450 °C. Also, thermal spray of Ti 2 AlC powder has been used to produce thick coatings. We further treat progress in the use of first-principles calculations for predicting hypothetical MAX phases and their properties. Together with advances in processing and materials 3 analysis, this progress has led to recent discoveries of numerous new MAX phases such as Ti 4 SiC 3 , Ta 4 AlC 3 , and Ti 3 SnC 2 . Finally, important future research directions are discussed. These include charting the unknown regions in phase diagrams to discover new equilibrium and metastable phases, as well as research challenges in understanding their physical properties, such as the effects of anisotropy, impurities, and vacancies on the electrical properties, and unexplored properties such as superconductivity, magnetism, and optics. 4

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Section: Discussionmentioning

confidence: 99%

The M+1AX phases: Materials science and thin-film processing

et al. 2010

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“…an unexpected combination of metallic and ceramic attributes. These combinations of properties place this class of materials as highly functional with the following aspects: (i) MAX phases can be easily machined like metals, (ii) they have good oxidation properties like ceramics, and (iii) they are excellent electrical and thermal conductors [1][2][3][4][5][6][7][8]. Among the ternary phases almost all the studies are concerned with carbide properties, but with few works on nitrides.…”

Section: Introductionmentioning

confidence: 99%

Superconductivity at 7.3 K in Ti2InN

Bortolozo

Serrano

Serquis

et al. 2010

Solid State Communications

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a b s t r a c tIn this work the Ti 2 InN phase is investigated by X-ray diffraction, magnetic and resistivity measurements. X-ray powder patterns suggest that all peaks can be indexed with the hexagonal phase of Cr 2 AlC prototype. Electrical resistance as a function of temperature reveals superconductivity below 7.3 K. M(H) hysteresis loops show typical type-II superconductivity. Using R(H) versus T measurements we estimated

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“…MAX phases are kinking-nonlinear elastic solids which can dissipate significant amount of energy during cyclic loading due to the formation and annihilation of fully reversible incipient kink bands. [31] Previous investigations have shown exceptional damage tolerance of MAX phase foams. [25] Specifically, the compressive strength of Ti 2 AlC decreases almost linearly with increasing porosity and less rapidly when compared with common ceramics, such as Al 2 O 3 , Si 3 N 4 , and ZrO 2 , whose compressive strength drops dramatically with increasing porosity.…”

Section: Resultsmentioning

confidence: 97%

Current-Activated, Pressure-Assisted Infiltration: A Novel, Versatile Route for Producing Interpenetrating Ceramic–Metal Composites

Kothalkar

O'Neil

et al. 2014

Materials Research Letters

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A novel technique is proposed and demonstrated for processing interpenetrating ceramic-metal composites by the infiltration of molten metals/alloys into ceramic foams utilizing a current-activated, pressure-assisted technique. Ti 2 AlC foams were prepared and used as the infiltration preform. Aluminum alloy 6061 (AA6061) has been infiltrated into the Ti 2 AlC foams, resulting in AA6061/Ti 2 AlC composites. The microstructure, composition, and distribution of phases in the composites were studied. The AA6061/Ti 2 AlC composites were studied under compression testing, and the results were compared with those of the pure components of the composites. Advantages of this method in comparison to other methods for processing metal-ceramic composites are discussed.

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Fully reversible, dislocation-based compressive deformation of Ti3SiC2 to 1 GPa

Cited by 347 publications

References 22 publications

The M+1AX phases: Materials science and thin-film processing

The M+1AX phases: Materials science and thin-film processing

Superconductivity at 7.3 K in Ti2InN

Current-Activated, Pressure-Assisted Infiltration: A Novel, Versatile Route for Producing Interpenetrating Ceramic–Metal Composites

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