Key Microstructures Controlling the Mechanical Properties of Two-Phase TiAl Alloys with Lamellar Structures

ABSTRACTThe objective of this study is to identify key microstructural parameters which control the mechanical properties of two-phase γ-TiAl alloys with lamellar structures. TiAl alloys with the base composition of Ti-47Al-2Cr-2Nb (at. %) were prepared by arc melting and drop casting, followed by hot extrusion at temperatures above the oc-transus temperature, Tα. The hot extruded materials were then heat treated at various temperatures above and below Tα in order to control microstructural features in these lamellar structures. The mechanical properties of these alloys were determined by tensile testing at temperatures to 1000° C. The tensile elongation at room temperature is strongly dependent on grain size, showing an increase in ductility with decreasing grain size. The strength at room and elevated temperatures is sensitive to interlamellar spacing, showing an increase in strength with decreasing lamellar spacing. Hall-Petch relationships hold well for the yield strength at room and elevated temperatures and for the tensile elongation at room temperature. Tensile elongations of about 5% and yield strengths around 900 MPa are achieved by controlling both colony size and interlamellar spacing. The mechanical properties of the TiAl alloys with controlled lamellar structures produced directly by hot extrusion are much superior to those produced by conventional thermomechanical treatments.

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Ultrafine Fully-Lamellar Structures in Two-Phase γ-TiAl Alloys

MRS Proceedings ◽

10.1557/proc-460-219 ◽

1996 ◽

Vol 460 ◽

Cited By ~ 2

Author(s):

P. J. Maziasz ◽

C. T. Liu

Keyword(s):

Room Temperature ◽

Interlamellar Spacing ◽

Hot Extrusion ◽

Processing Parameters ◽

High Temperature Strength ◽

Two Phase ◽

Tial Alloys ◽

Room Temperature Ductility ◽

Heat Treated ◽

Fully Lamellar

ABSTRACTSpecial ultrafine fully-lamellar microstructures have been found recently in γ-TiAl alloys with 46–48 at.% Al, when they are processed or heat-treated above the α-transus temperature (Tα). Hot-extrusion above Tα also produces a refined colony or grain size. Refined-colony/ultrafine-lamellar (RC/UL) microstructures produce an excellent combination of room-temperature ductility and high-temperature strength in Ti-47Al-2Cr-2Nb (at.%) alloys. UL structures generally have an average interlamellar spacing of 100–200 nm, and have regularly alternating γ and α2 lamellea, such that they are dominated by γ/α2 interfaces with relatively few γ/γ twin boundaries. The focus of this study is how variations in processing parameters or alloy composition affect formation of the UL structure, particularly the α2 component.

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Mechanical Properties of Ultrafine Grained Two-Phase Titanium Alloy Produced by “abc” Deformation

Materials Science Forum ◽

10.4028/www.scientific.net/msf.706-709.1859 ◽

2012 ◽

Vol 706-709 ◽

pp. 1859-1863 ◽

Cited By ~ 2

Author(s):

Sergey V. Zherebtsov ◽

Sergey Kostjuchenko ◽

Egor A. Kudryavtsev ◽

Svetlana Malysheva ◽

Maria A. Murzinova ◽

...

Keyword(s):

Mechanical Properties ◽

Grain Size ◽

Titanium Alloy ◽

Impact Toughness ◽

Room Temperature ◽

Tensile Elongation ◽

Two Phase ◽

Ultrafine Grained ◽

Ultrafine Grained Microstructure ◽

Room Temperature Strength

The mechanical properties of two-phase Ti-6Al-4V titanium alloy with ultrafine grained microstructure were studied in the present work. Bulk ultrafine grained specimens of the alloy were produced by means of warm “abc” deformation. The final structure consisted of α/β particles with a size of 500 nm. Extensive studies of the mechanical properties of this material in comparison with conventionally heat-strengthened condition were conducted. A room-temperature strength and fatigue resistance of the ultrafine grained material was found to be 25-40% higher than that of heat-strengthened alloy. However such ductility related properties as tensile elongation and impact toughness noticeably decreased with decreasing grain size. Efficacy of ductility improvement and the strength/ductility balance optimization were analyzed.

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Microstructures and Mechanical Properties of NiAl+Mo In-Situ Eutectic Composites

MRS Proceedings ◽

10.1557/proc-194-147 ◽

1990 ◽

Vol 194 ◽

Cited By ~ 6

Author(s):

P. R. Subramanian ◽

M. G. Mendiratta ◽

D. B. Miracle ◽

D. M. Dimiduk

Keyword(s):

Mechanical Properties ◽

Solid Solution ◽

Room Temperature ◽

Composite System ◽

Elevated Temperatures ◽

Two Phase ◽

Structural Applications ◽

Temperature Fracture

AbstractThe quasibinary NiAI-Mo system exhibits a large two-phase field between NiAl and the terminal (Mo) solid solution, and offers the potential for producing in-situ eutectic composites for high-temperature structural applications. The phase stability of this composite system was experimentally evaluated, following long-term exposures at elevated temperatures. Bend strengths as a function of temperature and room-temperature fracture toughness data are presented for selected NiA1-Mo alloys, together with results from fractography observations.

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Microstructure and Mechanical Properties of Mechanically Alloyed NiAl

MRS Proceedings ◽

10.1557/proc-213-661 ◽

1990 ◽

Vol 213 ◽

Cited By ~ 4

Author(s):

S. J. Hwang ◽

P. Nash ◽

M. Dollar ◽

S. Dymek

Keyword(s):

Mechanical Properties ◽

Grain Size ◽

Dislocation Density ◽

Work Hardening ◽

Room Temperature ◽

Hot Extrusion ◽

Homogeneous Distribution ◽

Mechanically Alloyed ◽

Oxide Particles ◽

Temperature Work

ABSTRACTMechanical alloying (MA) has been used to produce NiAl powders from either elemental or prealloyed constituents. The powders were consolidated by hot extrusion resulting in material which was fully dense, with a grain size around 1 μm and a homogeneous distribution of oxide particles with sizes in the range 10 to 100 nm. TEM observation indicates the presence of a significant dislocation density after consolidation. Mechanical properties have been studied by compression testing from room temperature to 1300 K in air. Yield strengths ranged from 1453 MPa to 32 MPa depending on material and test temperature. Work hardening was observed at all test temperatures for both materials. Substantial ductility was observed even at room temperature where it exceeds 7.5 %. The effects of microstructure on the mechanical properties are discussed.

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Microstructural Studies of the Deformation of TiAl Alloys

MRS Proceedings ◽

10.1557/proc-133-693 ◽

1988 ◽

Vol 133 ◽

Cited By ~ 5

Author(s):

Ernest L. Hall ◽

Shyh-Chin Huang

Keyword(s):

Room Temperature ◽

Single Phase ◽

Elevated Temperatures ◽

Alloy Composition ◽

Two Phase ◽

Tial Alloys ◽

Second Phases ◽

Bend Tests ◽

Microstructural Studies ◽

Strength And Ductility

ABSTRACTThe mechanical behavior and microstructures of TiAl alloys after tensile and bend tests at room temperature and elevated temperatures were studied. The results for two-phase Ti52Al48 alloys are compared with those of single phase Ti48Al52, and the effect of adding 3 at. pct. vanadium as a substitute for Ti in these two alloys is considered. It is shown that Ti52Al48 has greater strength and ductility than Ti48Al52 at room temperature and elevated temperatures up to 871°C (1600°F). Adding vanadium increases the ductility of both binary alloys. The microstructure of the Ti52Al48 alloy deformed at room temperature contains primarily twins and 1/2<110> easy slip dislocations, whereas the similar Ti48Al52 sample exhibits superdislocations and associated pinned faulted dipoles. If these samples are deformed at 540°C (1000°F) or above, the Ti52Al48 exhibits extensive twinning, and the pinned faulted dipoles in the Ti48Al52 sample disappear. The vanadium additions do not noticeably change the deformation microstructure at room temperature. It is suggested that the strength and ductility of these alloys may be controlled by tetragonality, bonding, interstitial element, and grain size effects, which in turn are affected by the presence of second phases and by the alloy composition.

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Mechanical Properties and Dislocation Structure of Single Crystal Cdte Deformed in Compression at 300°C

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s042482010009292x ◽

1976 ◽

Vol 34 ◽

pp. 592-593

Author(s):

Ernest L. Hall ◽

J. B. Vander Sande

Keyword(s):

Mechanical Properties ◽

Single Crystal ◽

Dislocation Structure ◽

Room Temperature ◽

Elevated Temperatures ◽

Strain Curve ◽

Optical Devices ◽

Semiconductor Compound ◽

Wide Range ◽

Sample Orientation

The present paper describes research on the mechanical properties and related dislocation structure of CdTe, a II-VI semiconductor compound with a wide range of uses in electrical and optical devices. At room temperature CdTe exhibits little plasticity and at the same time relatively low strength and hardness. The mechanical behavior of CdTe was examined at elevated temperatures with the goal of understanding plastic flow in this material and eventually improving the room temperature properties. Several samples of single crystal CdTe of identical size and crystallographic orientation were deformed in compression at 300°C to various levels of total strain. A resolved shear stress vs. compressive glide strain curve (Figure la) was derived from the results of the tests and the knowledge of the sample orientation.

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On the use of Ozawa/Flynn/Wall method to determine aging activation energy for elastomers

Journal of Elastomers & Plastics ◽

10.1177/00952443211020330 ◽

2021 ◽

pp. 009524432110203

Author(s):

Sudhir Bafna

Keyword(s):

Mechanical Properties ◽

Activation Energy ◽

Weight Loss ◽

Oxygen Consumption ◽

Dwell Time ◽

Room Temperature ◽

Elevated Temperatures ◽

Degradation Mechanism ◽

Kinetics Of ◽

Wall Method

It is often necessary to assess the effect of aging at room temperature over years/decades for hardware containing elastomeric components such as oring seals or shock isolators. In order to determine this effect, accelerated oven aging at elevated temperatures is pursued. When doing so, it is vital that the degradation mechanism still be representative of that prevalent at room temperature. This places an upper limit on the elevated oven temperature, which in turn, increases the dwell time in the oven. As a result, the oven dwell time can run into months, if not years, something that is not realistically feasible due to resource/schedule constraints in industry. Measuring activation energy (Ea) of elastomer aging by test methods such as tensile strength or elongation, compression set, modulus, oxygen consumption, etc. is expensive and time consuming. Use of kinetics of weight loss by ThermoGravimetric Analysis (TGA) using the Ozawa/Flynn/Wall method per ASTM E1641 is an attractive option (especially due to the availability of commercial instrumentation with software to make the required measurements and calculations) and is widely used. There is no fundamental scientific reason why the kinetics of weight loss at elevated temperatures should correlate to the kinetics of loss of mechanical properties over years/decades at room temperature. Ea obtained by high temperature weight loss is almost always significantly higher than that obtained by measurements of mechanical properties or oxygen consumption over extended periods at much lower temperatures. In this paper, data on five different elastomer types (butyl, nitrile, EPDM, polychloroprene and fluorocarbon) are presented to prove that point. Thus, use of Ea determined by weight loss by TGA tends to give unrealistically high values, which in turn, will lead to incorrectly high predictions of storage life at room temperature.

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Is Superplasticity in the Future of Nanophase Materials?

MRS Proceedings ◽

10.1557/proc-196-59 ◽

1990 ◽

Vol 196 ◽

Cited By ~ 13

Author(s):

R. W. Siegel

Keyword(s):

Mechanical Properties ◽

Grain Size ◽

Room Temperature ◽

Grain Boundary Sliding ◽

Atomic Clusters ◽

Diffusional Creep ◽

Ultrafine Grain ◽

Grain Sizes ◽

Nanophase Materials ◽

Boundary Sliding

ABSTRACTThe ultrafine grain sizes and high diffusivities in nanophase materials assembled from atomic clusters suggest that these materials may have a strong tendency toward superplastic mechanical behavior. Both small grain size and enhanced diffusivity can be expected to lead to increased diffusional creep rates as well as to a significantly greater propensity for grain boundary sliding. Recent mechanical properties measurements at room temperature on nanophase Cu, Pd, and TiO2, however, give no indications of superplasticity. Nonetheless, significant ductility has been clearly demonstrated in these studies of both nanophase ceramics and metals. The synthesis of cluster-assembled nanophase materials is described and the salient features of what is known of their structure and mechanical properties is reviewed. Finally, the answer to the question posed in the title is addressed.

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Investigation of Mechanical Properties of Nanostructured Titanium Processed by Warm ECAP Followed Cold Rolling

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.875-877.63 ◽

2014 ◽

Vol 875-877 ◽

pp. 63-67 ◽

Cited By ~ 1

Author(s):

Dinh van Hai ◽

Nguyen Trong Giang

Keyword(s):

Mechanical Properties ◽

Grain Size ◽

Tensile Strength ◽

Cold Rolling ◽

Room Temperature ◽

Pure Titanium ◽

Rolling Process ◽

Coarse Grain ◽

Nanostructured Titanium

In this work, ECAP technique was combined with cold rolling process in order to enhance mechanical properties and microstructure of pure Titanium. Coarse grain (CG) Titanium with original grain size of 150 μm had been pressed by ECAP at 425oC by 4, 8 and 12 passes, respectively. This process then was followed by rolling at room temperature with 35%, 55%, and 75% rolling strains. After two steps, mechanical properties such as strength, hardness and microstructure of processed Titanium have been measured. The result indicated significant effect of cold rolling on tensile strength, hardness and microstructure of ECAP-Titanium.

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Comparison of Mechanical and Microstructural Properties of as-Cast Al-Cu-Mg-Ag Alloys: Room Temperature vs. High Temperature

Crystals ◽

10.3390/cryst11111330 ◽

2021 ◽

Vol 11 (11) ◽

pp. 1330

Author(s):

Muhammad Farzik Ijaz ◽

Mahmoud S. Soliman ◽

Ahmed S. Alasmari ◽

Adel T. Abbas ◽

Faraz Hussain Hashmi

Keyword(s):

Mechanical Properties ◽

High Temperature ◽

Mechanical Testing ◽

Tensile Testing ◽

Room Temperature ◽

Elevated Temperatures ◽

Microstructural Properties ◽

Testing Environments ◽

Mechanical And Microstructural Properties ◽

Mg Content

Unfolding the structure–property linkages between the mechanical performance and microstructural characteristics could be an attractive pathway to develop new single- and polycrystalline Al-based alloys to achieve ambitious high strength and fuel economy goals. A lot of polycrystalline as-cast Al-Cu-Mg-Ag alloy systems fabricated by conventional casting techniques have been reported to date. However, no one has reported a comparison of mechanical and microstructural properties that simultaneously incorporates the effects of both alloy chemistry and mechanical testing environments for the as-cast Al-Cu-Mg-Ag alloy systems. This preliminary prospective paper presents the examined experimental results of two alloys (denoted Alloy 1 and Alloy 2), with constant Cu content of ~3 wt.%, Cu/Mg ratios of 12.60 and 6.30, and a constant Ag of 0.65 wt.%, and correlates the synergistic comparison of mechanical properties at room and elevated temperatures. According to experimental results, the effect of the precipitation state and the mechanical properties showed strong dependence on the composition and testing environments for peak-aged, heat-treated specimens. In the room-temperature mechanical testing scenario, the higher Cu/Mg ratio alloy with Mg content of 0.23 wt.% (Alloy 1) possessed higher ultimate tensile strength when compared to the low Cu/Mg ratio with Mg content of 0.47 wt.% (Alloy 2). From phase constitution analysis, it is inferred that the increase in strength for Alloy 1 under room-temperature tensile testing is mainly ascribable to the small grain size and fine and uniform distribution of θ precipitates, which provided a barrier to slip by deaccelerating the dislocation movement in the room-temperature environment. Meanwhile, Alloy 2 showed significantly less degradation of mechanical strength under high-temperature tensile testing. Indeed, in most cases, low Cu/Mg ratios had a strong influence on the copious precipitation of thermally stable omega phase, which is known to be a major strengthening phase at elevated temperatures in the Al-Cu-Mg-Ag alloying system. Consequently, it is rationally suggested that in the high-temperature testing scenario, the improvement in mechanical and/or thermal stability in the case of the Alloy 2 specimen was mainly due to its compositional design.

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