27 results on '"Das, J"'
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2. Effect of Zr Addition on Microstructure, Hardness and Oxidation Behavior of Arc-Melted and Spark Plasma Sintered Multiphase Mo-Si-B Alloys.
- Author
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Kumar, N. K., Das, J., and Mitra, R.
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ZIRCONIUM alloys ,MICROSTRUCTURE ,OXIDATION ,HEAT resistant alloys ,JET engines - Abstract
The effect of 2 at. pct Zr addition at the expense of Mo on microstructural evolution, hardness as well as non-isothermal and isothermal oxidation behavior of arc-melted or spark-plasma sintered (SPS) 76Mo14Si10B and 79.5Mo12Si8.5B alloys, has been examined. The microstructures of both arc-melted and SPS alloys have exhibited α-Mo, Mo
3 Si and Mo5 SiB2 .These alloys, particularly those processed by SPS have also shown dispersion of SiO2 particles, and these are largely replaced by ZrO2 at interphase boundaries in the Zr-containing alloys. Alloying with Zr or processing by SPS has led to refinement of microstructure, which in turn has caused significant hardness enhancement. During heating from ambient temperature to 1250 °C in air inside a thermogravimetric analyzer, initial mass gain at ≈ 800 °C is found to be followed by rapid mass loss. Isothermal oxidation studies in the temperature range of 800 °C-1300 °C have shown initial mass loss caused by vaporization of MoO3 being followed by a regime of no change in mass. Besides B2 O3 -SiO2 , MoO2 and Mo have been found in the oxide scales of all alloys, whereas ZrO2 and ZrSiO4 have been found along with Zr(MoO4 )2 in case of Zr-containing alloys. Reduced mass loss is observed in Zr-containing alloys with the maximum improvement being observed for exposure at 800 °C, not only due to higher volume fractions of Mo3 Si and Mo5 SiB2 contributing to formation of B2 O3 -SiO2 , but also because MoO3 is partly consumed to form non-volatile Zr(MoO4 )2 . Furthermore, refinement of microstructures obtained by Zr addition or processing by SPS increases the net area covered by interphase interfaces, which provides short circuit paths for diffusion and enhances the kinetics of formation of protective B2 O3 -SiO2 scale. [ABSTRACT FROM AUTHOR]- Published
- 2019
- Full Text
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3. Synthesis of mullite-based coatings from alumina and zircon powder mixtures by plasma spraying and laser remelting.
- Author
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Hazra, S., Das, J., and Bandyopadhyay, P.P.
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MULLITE synthesis , *SURFACE coatings , *ALUMINUM oxide , *ZIRCON , *POWDER metallurgy , *PLASMA spraying , *LASER beams - Abstract
A mechanical mixture of alumina and pulverized zircon sand in 3:2 M ratio has been plasma sprayed to obtain mullite coating. Thereafter, the top layer of the coating has been remelted using laser. The presence of a mullite phase in the as-sprayed and laser remelted coatings has been confirmed qualitatively using X-ray diffraction. Both as-sprayed and laser remelted coatings have been characterized for their microstructure, hardness and porosity. The ultrafine grain structure of the coating produced by rapid quenching has been analyzed using transmission electron microscope. Presence of a mullite phase in the coatings has also been confirmed using small angle electron diffraction. Laser remelting has resulted in an appreciable reduction in porosity and increase in hardness in the coatings. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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4. X-Ray Photoelectron Spectra of La0.67Ca0.33MnO3 Processed by EATPAH Technique.
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Mishra, D. K., Dash, S., Samantray, S., Pradhan, S. K., Das, J., Varma, S., and Roul, B. K.
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LANTHANUM compounds ,X-ray photoelectron spectroscopy ,MAGNETORESISTANCE ,PLASMA heating ,ELECTRON probe microanalysis ,MICROSTRUCTURE - Abstract
La
0.67 Ca0.33 MnO3 (LCMO) colossal magnetoresistance (CMR) materials were sintered to highly dense products by an extended arc thermal plasma assisted heating (EATPAH) technique within a short sintering time of 2.5 minutes as compared to conventional long range heating schedule (few hours of time). 2.5 minutes plasma sintered LCMO showed enhanced Tc (272 K), which is closed to TIM (275 K) [1] as compared to the conventional sintered LCMO sample. Specimens are analyzed by X-ray Photoelectron Spectra (XPS) and electron probe microstructure analysis (EPMA) to get idea on elemental distribution and valence spectra of all the elements present in the specimen. The binding energy of La, Ca & Mn are analogous to the conventional sintered LCMO and to the reference spectra [2]. [ABSTRACT FROM AUTHOR]- Published
- 2008
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5. Microstructure and size effect in ultrafine (Ti0.705Fe0.295)100 − x Sn x (0⩽ x ⩽4at.%) composites.
- Author
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Maity, T. and Das, J.
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TITANIUM compounds , *METAL microstructure , *METALLIC composites , *STRAINS & stresses (Mechanics) , *DISLOCATION density , *MECHANICAL properties of metals - Abstract
Highlights: [•] Effect of Sn on the indentation size effect in Ti–Fe–(Sn) has been explored. [•] Fitting through ISE models point the existence of strain gradient beneath indenter. [•] Correlation has been established between dislocation density, grain size and ISE. [•] ISE in Ti–Fe–Sn ultrafine composites requires a dislocation density of ∼1014–1016/m2. [Copyright &y& Elsevier]
- Published
- 2014
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6. No room temperature ferromagnetism in Mn over-doped Zn1−x Mn x O (x>0.02)
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Das, J., Mishra, D.K., Sahu, D.R., Pradhan, S.K., and Roul, B.K.
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FERROMAGNETISM , *ZINC oxide , *MANGANESE compounds , *TEMPERATURE effect , *MICROSTRUCTURE , *SCANNING electron microscopes , *X-ray diffraction - Abstract
Abstract: Mn-doped ZnO samples having composition Zn1−x Mn x O (x=0.02, 0.04 and 0.05) were synthesized by solid state reaction technique with varying concentration of Mn from 0.02 to 0.05. Evidence of room temperature ferromagnetism was observed only in the composition Zn0.98Mn0.02O sintered at 500°C. Our XRD pattern confirms the presence of Mn3O4 impurity phase in all the Zn1−x Mn x O samples with the exception of Zn0.98Mn0.02O. We emphasize that the appearance of Mn3O4 phase in the system forbids the exchange type of interaction between the Mn ions and suppresses the ferromagnetism in all the Mn over-doped Zn1−x Mn x O (x>0.02) system. SEM microstructure study also supports the interruption of exchange type of interaction inside the system with the increase in Mn concentration in the sample. Interestingly, for this particular composition, Zn0.98Mn0.02O sintered at 500°C, glassy ferromagnetism type of transition is observed at low temperature. This type of transition is attributed to the formation of the oxides of Mn clusters at low temperature. [ABSTRACT FROM AUTHOR]
- Published
- 2011
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7. Oxidation behaviour of Mo–Si–B–(Al, Ce) ultrafine-eutectic dendrite composites in the temperature range of 500–700 °C
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Das, J., Mitra, R., and Roy, S.K.
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OXIDATION , *DENDRITIC crystals , *COMPOSITE materials , *COMPARATIVE studies , *TERNARY alloys , *ELECTRON microscopy , *MICROSTRUCTURE - Abstract
Abstract: A comparative study has been carried out to investigate the effects of Al and/or Ce additions on microstructure of Mo–Si–B alloys and their isothermal oxidation behaviour at 500 and 700 °C in laboratory air for 24 h. Microstructure of arc melted Mo–Si–B–(Al, Ce) alloys consists of bcc α-Mo dendrites embedded in ultrafine lamellar Mo3Si and Mo5SiB2 eutectic matrix. Isothermal oxidation kinetics of ultrafine structured Mo–Si–B alloy at 500 °C has been found to show hardly any mass change during 24 h exposure. Addition of Al to Mo–Si–B alloy refines the microstructure, decreases the net mass loss at 700 °C by ∼43%, whereas Ce does not bring about any significant change. The enhanced oxidation resistance of Mo–Si–B–Al alloy is due to the formation of Al–O rich inter-layer at the alloy/oxide interface along with the formation of a protective and dense Al2(MoO4)3 outer layer, which reduces the sublimation of MoO3 at 700 °C. Various transient/complex oxides formed on the alloys during their high temperature exposure have been examined to determine the oxidation mechanisms. [ABSTRACT FROM AUTHOR]
- Published
- 2011
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8. Effect of prestraining on the deformation and fracture behavior of Zr44Ti11Cu9.8Ni10.2Be25
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Lee, M.H., Das, J., Lee, K.S., Kühn, U., and Eckert, J.
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DEFORMATIONS (Mechanics) , *FRACTURE mechanics , *BULK solids , *METALLIC glasses , *MATERIALS compression testing , *STRESS concentration , *MICROSTRUCTURE - Abstract
Abstract: Mechanical prehistory is an important factor on the stability of the structure, and consideration of this issue is also useful for determining the mechanisms of post-deformation and fracture processes in bulk metallic glasses. We present investigations to reveal the effect of prestraining on the compressive deformation, morphology of the fracture surface and the evolution of microstructural inhomogeneity in Zr44Ti11Cu9.8Ni10.2Be25 (Vitreloy 1b) “brittle” bulk metallic glass (BMG). The intrinsic plasticity of the BMG increases linearly from 0.7% up to 15% plastic strain upon cold rolling up to 30% prestrain at room temperature due to the change of the short-range order of the glassy phase. Regions of river-like patterns appeared on the fracture surface of prestrained BMGs after compression test, which is similar to that appear during tensile deformation indicating the development of a deformation-induced inhomogeneous residual stress distribution. The effect of uniaxial cyclic compression on the flow stress of the as-cast BMG is also investigated. [ABSTRACT FROM AUTHOR]
- Published
- 2010
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9. Corrosion and pitting behaviour of ultrafine eutectic Ti–Fe–Sn alloys
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Sueptitz, R., Das, J., Baunack, S., Gebert, A., Schultz, L., and Eckert, J.
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EUTECTIC alloys , *TERNARY alloys , *ALLOYS , *CORROSION resistant materials , *MICROSTRUCTURE , *COPPER castings , *PASSIVITY (Chemistry) , *THIN films , *POLYCRYSTALS - Abstract
Abstract: Ultrafine structured Ti70.5Fe29.5 and Ti67.79Fe28.36Sn3.85 eutectic rods comprising of β-Ti and TiFe phases were prepared by copper mould casting. The corrosion and passivation behaviour were investigated in halide free aqueous media (pH 1–13) by means of potentiodynamic polarisation and potentiostatic current transient measurements. Both eutectic alloys exhibit excellent corrosion resistance due to spontaneous passivation. The passive film compositions grown several nanometres on single phase polycrystalline specimens were analyzed with Auger electron spectroscopy. They consist of oxidized Ti and Fe species. Layers grown in strongly acidic environment are depleted in Fe. Sn was detected only on layers grown on the constituent β-Ti phase and only in the metallic state. The pitting susceptibility was investigated in strongly acidic media (pH≤1) containing 0.1–3M of chloride ions. The Sn-containing eutectic alloy was found to be more susceptible to pitting corrosion. [Copyright &y& Elsevier]
- Published
- 2010
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10. Designing bulk metallic glass and glass matrix composites in martensitic alloys
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Das, J., Pauly, S., Boström, M., Durst, K., Göken, M., and Eckert, J.
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METALLIC glasses , *METALLIC composites , *MARTENSITE , *METAL microstructure , *MECHANICAL properties of metals , *INDENTATION (Materials science) , *SHAPE memory alloys , *COPPER-zirconium alloys - Abstract
Abstract: To circumvent the limited plasticity of bulk metallic glasses (BMGs), heterogeneous materials with glassy matrix and different type and length-scale of heterogeneities (micrometer-sized second phase particles or fibers, nanocrystals in a glassy matrix, phase separated regions, variations in short-range order by clustering) have been reported. We developed bulk metallic glasses and glass matrix composites in martensitic Zr–Cu-base alloys. Large plasticity can be obtained from microstructure consisting of either a glassy structure, or for alloys with martensitic second phase embedded in a glassy matrix. This type of glasses and glass–matrix composites are able to achieve high strength together with pronounced work-hardening. We explore the possibilities to synthesize such in situ composite microstructures based on shape memory alloys (“M-Glasses”) through metal mold casting. [Copyright &y& Elsevier]
- Published
- 2009
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11. Microstructural investigation of a deformed Ti66.1Cu8Ni4.8Sn7.2Nb13.9 nanostructure–dendrite composite
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Kim, K.B., Das, J., Baier, F., and Eckert, J.
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MICROMECHANICS , *MICROSTRUCTURE , *STEREOLOGY , *MORPHOLOGY - Abstract
Abstract: Investigation of the microstructure of a compressed Ti66.1Cu8Ni4.8Sn7.2Nb13.9 nanostructure–dendrite composite reveals that the deformed bcc β-Ti dendrites form a stepped morphology at the interfaces between the individual dendrites and the nanostructured matrix of hcp α-Ti and bct Ti2Cu phases. Furthermore, there is a unique stained contrast during the propagation and the interaction of the shear bands in the dendrites indicating a local structural change near to the apex of the shear bands in the dendrite. In contrast, the shear bands pass through coherent grain boundaries between the hcp α-Ti and the bct Ti2Cu phases of the nanostructured matrix. [Copyright &y& Elsevier]
- Published
- 2007
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12. Deformation behavior of a Ti66Cu8Ni4.8Sn7.2Nb14 nanostructured composite containing ductile dendrites
- Author
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Eckert, J., Das, J., Kim, K.B., Baier, F., Löser, W., Calin, M., Zhang, Z.F., and Gebert, A.
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DEFORMATIONS (Mechanics) , *ELASTICITY , *MATERIAL plasticity , *PLASTICS - Abstract
Abstract: The deformation behavior of multicomponent Ti66Cu8Ni4.8Sn7.2Nb14 composite containing primary dendrites embedded in a nanoeutectic matrix was studied under uniaxial compression. The evolution of slip and shear bands has been investigated at various stages of deformation. This type of advanced composite not only displays a high compressive plasticity of 31.8%, but also exhibits high fracture strength of ≈2.02GPa (true fracture strength 1.38GPa). Pronounced work hardening was observed after yielding. The surface deformation morphology reveals that the work hardening behavior of the composite is related to the plastic deformation of the dendritic phase through slip bands and the interaction of shear bands in the nanostructured matrix with the hardened dendrites. The nucleation of shear band occurs at a certain amount (8%) of plastic deformation at the dendrite–nanoeutectic matrix interface. The final stage of compression proceeds through passing of the shear bands through the work-hardened dendrites into the nanoeutectic matrix, whereby the propagation of the shear bands in the matrix is retarded by the nanoscale phases. [Copyright &y& Elsevier]
- Published
- 2007
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13. Microstructural comparison of Zr73.5Nb9Cu7Ni1Al9.5 nanostructure-dendrite composites produced by different casting techniques
- Author
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Kim, K.B., Das, J., Löser, W., Lee, M.H., Kim, D.H., Roy, S.K., and Eckert, J.
- Subjects
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MICROSTRUCTURE , *NANOSTRUCTURES , *DENDRITIC crystals , *METAL castings - Abstract
Abstract: Zr73.5Nb9Cu7Ni1Al9.5 (numbers indicate at.%) nanostructure-dendrite composites were fabricated using three different casting techniques: suction casting, centrifugal casting and arc-melting. The microstructure of the suction casting sample consists of micrometer-scale dendrites in a nanostructured matrix. However, some areas in the matrix contain nano-scale crystals together with an amorphous phase revealing an inhomogeneity of the specimen. On the contrary, the microstructures of the centrifugally-cast and the arc-melted samples are overall homogeneous, consisting of micrometer-scale dendrites that are homogeneously distributed in a nanostructured matrix. The dendrites correspond to a body centered cubic (bcc) β-Zr phase, whereas the nanostructured matrix consists of body centered tetragonal (bct) Zr2Cu-type and hexagonal close-packed (hcp) MgZn2-type phases. The comparison of the microstructures of these two alloys reveals that the formation of nano-scale twins and a disordered ω-phase in the β-Zr dendrites only happens in the centrifugally-cast sample. The differences in the phases and the microstructures between the differently prepared samples significantly influence the corresponding mechanical properties of the specimens. [Copyright &y& Elsevier]
- Published
- 2007
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14. Ti-base bulk nanostructure-dendrite composites: Microstructure and deformation
- Author
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Eckert, J., Das, J., He, G., Calin, M., and Kim, K.B.
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DENDRITIC crystals , *TITANIUM compounds , *NANOSTRUCTURES , *MICROSTRUCTURE - Abstract
Abstract: Bulk nanostructured/glassy Ti-base multicomponent alloys are attractive advanced high-strength materials for structural applications or as functional materials, e.g. for medical applications. Typically, the strength and elastic strain limits of such alloys are significantly higher than for conventional microcrystalline alloys. It is of strong interest to develop a one-step process that can directly produce such alloys in bulk form, e.g. through casting, with an in situ formed composite microstructure that combines phases with different desirable properties. Along this line, a series of (Ti–Zr–Ta)–Cu–Ni alloys designed from glass-forming alloy compositions with different volume fractions of β-Ti phase have been investigated. The introduction of the β-Ti dendritic solid solution phase enhances the ductility of the material. A further improvement can be achieved by adding isomorphous β-phase stabilizers in (Ti–Nb–Ta)–Si/In alloys. These alloys exhibit low elastic modulus (50GPa) and very large deformability (>100% plastic strain) at room temperature without appearance of any microcracks. The microstructure of these alloys consists of a high volume fraction of bcc β-Ti phase coexisting with a nanostructured interdendritic matrix. The superplastic-like deformability of the near beta alloys is correlated with copious twinning in the micrometer-size β-Ti-dendrites leading to a nano/ultrafine filamentary structure. [Copyright &y& Elsevier]
- Published
- 2007
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15. Microscopic deformation mechanism of a Ti66.1Nb13.9Ni4.8Cu8Sn7.2 nanostructure–dendrite composite
- Author
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Kim, K.B., Das, J., Xu, W., Zhang, Z.F., and Eckert, J.
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MICROSTRUCTURE , *DENDRITIC crystals , *SHEAR (Mechanics) , *NANOSTRUCTURED materials , *DEFORMATIONS (Mechanics) - Abstract
Abstract: Systematic investigations of the microstructural changes upon compression have been performed in order to elucidate the microscopic deformation mechanisms of the high-strength and ductile Ti66.1Nb13.9Ni4.8Cu8Sn7.2 nanostructure–dendrite composite. After 8% deformation, a rotation of β-Ti dendrites is observed during the interaction of slip and shear bands. This rotation leads to the formation of new slip bands in the dendrites. The β-Ti dendrites locally transform into ω phase during the interaction between the newly and the previously formed slip bands. The rotation of the dendrites causes local volume changes at the interfacial areas between the dendrites and the matrix, consisting of a mixture of hexagonal close-packed α-Ti and body-centered tetragonal Ti2Cu phases. This induces a rotational stress into the nanostructured matrix. After further deformation up to 25%, the shear bands penetrate the dendrite/matrix interfaces, producing extra interfaces. The nanostructured matrix exhibits a sandwiched microstructure in order to accommodate effectively the shear strains. These results suggest that structural coherency of the dendrite/matrix interfaces is important for controlling both the strength and the ductility of the nanostructure–dendrite composite. [Copyright &y& Elsevier]
- Published
- 2006
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16. Novel In Situ Nanostructure-Dendrite Composites in Zr-Base Multicomponent Alloy System.
- Author
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Das, J., Roy, S. K., Löser, W., Eckert, J., and Schultz, L.
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NANOSTRUCTURES ,DENDRITIC crystals ,MICROSTRUCTURE ,ALLOYS ,ZIRCONIUM alloys ,ZIRCONIUM - Abstract
The evolution of a nanostructure-dendrite composite microstructure of two Zr-base alloys solidified through different casting routes is presented. The alloys were designed by adding different amounts of Nb to the Zr-based multicomponent glass-forming alloy system. The refractory metal Nb promotes the formation of a primary phase having dendritic morphology, whereas the residual melt solidifies to a nanostructured/amorphous matrix. The volume fraction and the morphology of the dendritic phase varied with the Nb content and the adopted casting route. A correlation between the alloy composition and adopted casting method with evolved microstructures and mechanical properties is revealed. These composites exhibit a unique combination of high fracture strength up to 1922 Mpa, as well as plastic strain over 15.8% under uniaxial compression testing at room temperature. The high strength of these composites is imparted by the nanostructured matrix, whereas the large plastic strain is a consequence of the retardation of excessive localized shear banding in the matrix by ductile dendrites. The significant work hardening of the composites prior to fracture is attributed to dislocation multiplication in the solid solution-strengthened dendritic phase. [ABSTRACT FROM AUTHOR]
- Published
- 2004
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17. Formation of a bimodal eutectic structure in Ti–Fe–Sn alloys with enhanced plasticity.
- Author
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Han, J. H., Kim, K. B., Yi, S., Park, J. M., Sohn, S. W., Kim, T. E., Kim, D. H., Das, J., and Eckert, J.
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TITANIUM alloys ,EUTECTICS ,MATERIAL plasticity ,MICROSTRUCTURE ,SOLIDIFICATION - Abstract
Microstructural investigations on a series of (Ti
70.5 Fe29.5 )100-x Snx alloys with x=5, 7, and 9 reveal that Sn addition is effective in introducing both structural and spatial heterogeneities in ultrafine eutectic composites stemming from a large temperature difference between two eutectic temperatures upon solidification. The microstructural heterogeneities in these ultrafine eutectic composites strongly enhance the room temperature compressive plasticity up to ∼15.7%. [ABSTRACT FROM AUTHOR]- Published
- 2008
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18. Heterogeneity of a Cu47.5Zr47.5Al5 bulk metallic glass.
- Author
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K. B. Kim, Das, J., Baier, F., M. B. Tang, W. H. Wang, and Eckert, J.
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MICROSTRUCTURE , *COPPER , *ZINC , *METALLIC glasses , *INHOMOGENEOUS materials , *NANOSCIENCE - Abstract
Microstructural investigation of an as-cast Cu47.5Zr47.5Al5 bulk metallic glass (BMG) reveals two amorphous phases formed by liquid phase separation. The morphology of the phase separated amorphous regions is spherical with 10–20 nm in size. These areas are homogeneously distributed throughout the sample. Moreover, a macroscopic heterogeneity also occurs along with the nano-scale liquid phase separation. The macroscopic heterogeneity can be distinguished from the different degree of the chemical fluctuations in the sample, and the existence of nano-scale crystals of less than 5 nm in size. Presumably, both the macroscopic heterogeneity and the nano-scale phase separation enhance branching of the shear bands during deformation in the Cu47.5Zr47.5Al5 BMG. [ABSTRACT FROM AUTHOR]
- Published
- 2006
- Full Text
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19. Influence of additional elements on the development of nanoscale heterogeneities in (TiCu)-based bulk metallic glasses with enhanced ductility.
- Author
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Zhang, X. F., Kim, K. B., Das, J., Yi, S., and Eckert, J.
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MICROSTRUCTURE ,METALLIC glasses ,HEAT of mixing ,NANOCHEMISTRY ,SOLIDIFICATION ,ALLOYS - Abstract
The effect of additional elements on microstructure and mechanical properties of (TiCu)-based bulk metallic glasses (BMGs) has been systematically investigated. Based on the values of the heat of mixing between the additional elements and the major constituent elements Ti and Cu, small additions of elements having a positive heat of mixing with Cu and a negative heat of mixing with Ti are effective in forming nanoscale heterogeneities upon solidification and enhance the ductility. It is experimentally demonstrated that the selection of the minor elements in (TiCu)-based BMGs plays a crucial role to induce nanoscale heterogeneities and thus to control the deformation behavior of the bulk metallic glasses. [ABSTRACT FROM AUTHOR]
- Published
- 2007
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20. Microstructure and mechanical properties of slowly cooled Cu47.5Zr47.5Al5.
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Das, J., Pauly, S., Duhamel, C., Wei, B. C., and Eckert, J.
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MICROSTRUCTURE ,MECHANICAL properties of metals ,COPPER alloys ,ZIRCONIUM alloys ,ALUMINUM alloys ,METALLIC glasses - Abstract
Cu
47.5 Zr47.5 Al5 was prepared by arc melting and solidified in situ by suction casting into 2-5-mm-diameter rods under various cooling rates (200-2000 K/s). The microstructure was investigated along the length of the rods by electron microscopy, differential scanning calorimetry and mechanical properties were investigated under compression. The microstructure of differently prepared specimens consists of macroscopic spherical shape chemically inhomogeneous regions together with a low volume fraction of randomly distributed CuZr B2 phase embedded in a 2-7 nm size clustered "glassy-martensite" matrix. The as-cast specimens show high yield strength (1721 MPa), pronounced work-hardening behavior up to 2116 MPa and large fracture strain up to 12.1-15.1%. The fracture strain decreases with increasing casting diameter. The presence of chemical inhomogenities and nanoscale "glassy-martensite" features are beneficial for improving the inherent ductility of the metallic glass. [ABSTRACT FROM AUTHOR]- Published
- 2007
- Full Text
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21. Mechanism of lamellae deformation and phase rearrangement in ultrafine β-Ti/FeTi eutectic composites.
- Author
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Maity, T., Roy, B., and Das, J.
- Subjects
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REARRANGEMENTS (Chemistry) , *DEFORMATIONS (Mechanics) , *EUTECTICS , *COMPOSITE materials , *MICROSTRUCTURE - Abstract
We report the microscopic mechanism of lamellae deformation in a series of (Ti 0.705 Fe 0.295 ) 100− x Sn x (0 ⩽ x ⩽ 4) eutectic comprising of ultrafine FeTi and β-Ti phases with varying lamellae thickness. Furthermore, the microstructural refinement and phase rearrangement upon severe forging have been explored using X-ray diffraction and transmission electron microscopy to reveal the dislocation activity inside the lamellae interior and at the β-Ti/FeTi interface. Nanoindentation tests have been performed at control loading rate and control strain rate modes to evaluate the strain rate sensitivity, activation volume, and to compare them with that of the constituent single phases. The strain rate sensitivity slightly decreases upon Sn addition and with the decrease of the lamellar spacing. However, severe forging increases the hardness, reduces the activation volume without any change of the strain rate sensitivity. The role of dislocation accumulation in the ultrafine lamellae, inter-lamellar sliding, formation of sub-boundaries, evolution of shear bands, cutting, and phase rearrangement towards the deformation-induced nanostructuring of the ultrafine lamellar composites, have been discussed using a micromechanical model. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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22. Improved plasticity of bulk metallic glasses upon cold rolling
- Author
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Lee, M.H., Lee, K.S., Das, J., Thomas, J., Kühn, U., and Eckert, J.
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MATERIAL plasticity , *METALLIC glasses , *ROLLING (Metalwork) , *ZIRCONIUM alloys , *STRAINS & stresses (Mechanics) , *MICROSTRUCTURE , *TEMPERATURE effect , *NUCLEATION , *MATERIALS compression testing - Abstract
The intrinsic plasticity of Zr44Ti11Cu9.8Ni10.2Be25 and Zr55Ti5Al10Cu20 Ni10 bulk metallic glasses (BMGs) are improved from 0.5% up to 15% plastic strain due to the introduction of microstructural inhomogeneities upon cold rolling at room temperature. This approach shows an easy way to overcome the intrinsic brittleness of the BMGs by modifying their physical properties, which enables easy nucleation and branching of multiple shear bands upon unconstrained loading during the compression test. [Copyright &y& Elsevier]
- Published
- 2010
- Full Text
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23. Effect of Fe addition and moist environment on the high temperature oxidation behavior of Mo76-xSi14B10Fex (x = 0, 0.5, 1 at.%) composites.
- Author
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Kumar, N.K., Mitra, R., and Das, J.
- Subjects
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MOLYBDENUM disilicide , *ENERGY dispersive X-ray spectroscopy , *HIGH temperatures , *ISOTHERMAL temperature , *OXIDATION - Abstract
The effect of Fe addition and the moist environment on the high temperature isothermal oxidation behaviors of multiphase Mo 76- x Si 14 B 10 Fe x (x = 0, 0.5, 1 at.%) composites in the range of 1000–1300 °C have been investigated. The microstructure of all the composites with α–Mo solid solution (SS) and eutectic mixture of Mo 3 Si + Mo 5 SiB 2 phases, has been refined upon Fe addition, which improves the oxidation resistance and reduces the mass loss up to 55% in dry air and 31% in moist air for 24 h exposure. Whereas, the oxidation resistance in moist air improves due to the formation of a protective Fe-rich glassy borosilicate scale, which reduces the vaporization of MoO 3 by forming Fe 2 (MoO 4) 3. The cross-sectional area of the residual alloy for x = 1 were estimated to be 97% in dry air and 85% in moist air that of unoxidized coupons. The bulk hardness of the as-cast composite is 1031 Hv for x = 1, which reduced only by 6.7% (962 Hv) upon oxidation at 1300 °C in both dry and moist air, showing superior stability of the silicide matrix composites for high temperature application. X-ray diffraction, scanning electron microscopy and energy dispersive x-ray spectroscopy studies were performed to identify the various products of oxidation and to explore the mechanism of protection. • Oxidation behaviour of Mo 76- x Si 14 B 10 Fe x at 1000–1300 °C has been studied. • Moist air improves the mass loss by 31% during isothermal oxidation. • Fe addition improves the oxidation resistance in both dry and moist air. [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
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24. Microscopic mechanism on the evolution of plasticity in nanolamellar γ-Ni/Ni5Zr eutectic composites.
- Author
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Maity, T., Singh, A., Dutta, A., and Das, J.
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NANOCOMPOSITE materials , *MATERIAL plasticity , *EUTECTIC alloys , *MICROSTRUCTURE , *NICKEL alloys , *MECHANICAL properties of metals , *STRAIN rate - Abstract
The evolution of microstructure and the mechanical properties of a series of (Ni 0.912 Zr 0.088 ) 100- x Al x (0≤ x ≤4) eutectic composites, constitute of γ-Ni and Ni 5 Zr nanolamellar phases, have been presented. Al dissolves in γ-Ni phase preferentially, decreases its hardness and refines the microstructure. Strain rate jump test was performed in order to investigate the rate sensitivity. It has been found that activation volume increases from 39 b 3 to 46 b 3 upon Al addition. The strain rate sensitivity of the composites has been estimated to be ~0.008. The scanning and transmission electron microscopic studies have confirmed that dislocation meditated flow in nano-lamellar phases dominates the plastic deformation mechanism. Analysis based on Stroh's pile-up model suggests that the required shear stress for slip decreases and that for cleavage crack nucleation increases around a dislocation pile-up at the lamellae interface, upon Al addition. The nano-lamellar Ni 5 Zr strengthen the composite, whereas, dislocation slip endorses the global plasticity of high strength Ni-Zr-(Al) nanoeutectic composites. [ABSTRACT FROM AUTHOR]
- Published
- 2016
- Full Text
- View/download PDF
25. Improvement of oxidation resistance of arc-melted Mo76Si14B10 by microstructure control upon minor Fe addition.
- Author
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Kumar, N.K., Roy, B., Mitra, R., and Das, J.
- Subjects
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MICROSTRUCTURE , *MOLYBDENUM compounds , *OXIDATION , *EFFECT of temperature on metals , *INGOTS - Abstract
Addition of Fe refines the microstructure of Mo 76-x Si 14 B 10 Fe x ( x = 0, 0.5, 1 at.%) composites containing α-Mo, Mo 3 Si and Mo 5 SiB 2 phases, increases the hardness from 950 Hv ( x = 0) to 1031 Hv ( x = 1), and improves the oxidation resistance at temperature in the range of 800–1300 °C. The hardness of the base alloy substrate decreases only by <7% than that of as-solidified ingots, indicating good microstructural stability of the composite for high temperature application. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
26. Microstructural inhomogeneities introduced in a Zr-based bulk metallic glass upon low-temperature annealing
- Author
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Van Steenberge, N., Concustell, A., Sort, J., Das, J., Mattern, N., Gebert, A., Suriñach, S., Eckert, J., and Baró, M.D.
- Subjects
- *
INHOMOGENEOUS materials , *METALLIC glasses , *AMORPHOUS substances , *HEAT treatment of metals - Abstract
Abstract: Due to their exceptionally high yield strength and yield strain as compared to conventional metallic materials, bulk metallic glasses (BMGs) represent a class of promising engineering materials for structural applications. However, inhomogeneous deformation and severe shear localization at ambient temperature often lead to early failure and limit their reliability as structural materials. Heat treatments around the glass transition temperature (T g) generally aggravate the intrinsic brittleness of BMGs. In this paper, we report on the evolution of a nanoscale inhomogeneous microstructure upon low-temperature annealing in a Zr55Cu30Al10Ni5 BMG. This important outcome is explained by the experimentally observed tendency for chemical decomposition between Cu and Zr of the investigated amorphous system and is in accordance with literature data on various Zr–Cu-based amorphous alloys. Finally, these local fluctuations influence the plasticity of BMGs beneficially, in contrast of the generally accepted embrittlement upon annealing. [Copyright &y& Elsevier]
- Published
- 2008
- Full Text
- View/download PDF
27. Effect of Cu on local amorphization in bulk Ni–Ti–Zr–Si alloys during solidification
- Author
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Kim, K.B., Yi, S., Choi-Yim, H., Das, J., Xu, W., Johnson, W.L., and Eckert, J.
- Subjects
- *
MICROSTRUCTURE , *ALLOYS , *MORPHOLOGY , *NANOSCIENCE , *INTERMETALLIC compounds - Abstract
Abstract: Systematic investigations of the microstructure of Ni50Ti33Zr16Si1, Ni45Cu5Ti33Zr16Si1 and Ni40Cu10Ti33Zr16Si1 slowly cooled bulk specimens reveal the local occurrence of an amorphous phase in these alloys. The sites and the morphology of the amorphous phase strongly depend on the presence of Cu. The formation of a nanoscale amorphous phase in the Cu-free Ni50Ti33Zr16Si1 alloy is observed within the primary solidified Ni50(Ti,Zr)50 intermetallic compound with an isolated morphology. In contrast, in the Cu-containing alloys, Ni45Cu5Ti33Zr16Si1 and Ni40Cu10Ti33Zr16Si1, local amorphization occurs at negatively curved interfacial areas between the primary Ni50(Ti,Zr)50 grains and the Ni3Ti and NiTiZr matrix phases. Chemical analysis of the different phases in these alloys reveals that the amorphous phase is more Zr-rich compared to the primary Ni50(Ti,Zr)50 phase, indicating that the Zr content is very crucial for enhancing the glass-forming ability. However, Cu is decisive in controlling the volume fraction, the morphology and the sites of the amorphous phase in these alloys. [Copyright &y& Elsevier]
- Published
- 2006
- Full Text
- View/download PDF
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