Localized pore evolution assisted densification during spark plasma sintering of nanocrystalline W-5wt.%Mo alloy

Abstract: The present work reports the role of different atomic mobility induced localized pore evolution on densification during spark plasma sintering of nanocrystalline W-Mo alloy powder. The shrinkage (or expansion) behavior of cold compacted milled powders was studied using dilatometry during non-isothermal sintering up to 1600 °C. Subsequently, the milled powders were densified to ~95% relative density using spark plasma sintering up to 1600 °C. The enhanced localized Joule heating due to dynamically evolved porou… Show more

“…Almost similar grain sizes, irrespective of the densification process, suggests the same origin of microstructural stability during the sintering process. It is worth noting here that the pure W processed under similar conditions results in grain sizes almost 6.5 times bigger than in the present case [23].…”

“…The pronounced expansion can be well understood in view of a Kirkendall effect arising from the different atomic mobilities of W and Ta as reported by Lenz and Riley [19]. The Kirkendall porosity might play a major role in the early expansion of W-Ta, followed by a sudden drop as shrinkage caused by enhanced interdiffusion at higher temperatures and aided by alloying where the Kirkendall effect plays its role in a positive way [20,23]. Almost similar grain sizes, irrespective of the densification process, suggests the same origin of microstructural stability during the sintering process.…”

“…X-ray diffraction profile of mechanically milled W-5wt.%Ta alloy powder was collected using an X'Pert Pro (PANalytical, The Netherlands) X-ray diffractometer with Cu-Kα radiation in the 2θ range 10-140° using 0.02° step size with a 30 s time per step. A lineprofile analysis [23][24][25][26] was used for profile fitting using the pseudo-Voigt function in High Score Plus software (version 3.0e). Furthermore, the full width at half-maximum (FWHM) and the shape parameter (η) from the fitted profile were used as input parameters for the double-Voigt analysis [27,28] using the BREADTH programme (version 4) [29] for the quantification of crystallite size and root-mean-square strain (RMSS) in the milled powder sample.…”

“…The process can facilitate a high degree of densification at the lowest temperatures and for shorter periods with better grain refinement [21,22]. Moreover, Srivastav et al [23] has shown that localised diffusion-couple-induced pore evolution could be advantageous for densifying such materials by adopting the SPS process on account of the inherent localised heating mechanisms.…”

Microstructure evolution and densification during spark plasma sintering of nanocrystalline W-5wt.%Ta alloy

“…Almost similar grain sizes, irrespective of the densification process, suggests the same origin of microstructural stability during the sintering process. It is worth noting here that the pure W processed under similar conditions results in grain sizes almost 6.5 times bigger than in the present case [23].…”

“…The pronounced expansion can be well understood in view of a Kirkendall effect arising from the different atomic mobilities of W and Ta as reported by Lenz and Riley [19]. The Kirkendall porosity might play a major role in the early expansion of W-Ta, followed by a sudden drop as shrinkage caused by enhanced interdiffusion at higher temperatures and aided by alloying where the Kirkendall effect plays its role in a positive way [20,23]. Almost similar grain sizes, irrespective of the densification process, suggests the same origin of microstructural stability during the sintering process.…”

“…X-ray diffraction profile of mechanically milled W-5wt.%Ta alloy powder was collected using an X'Pert Pro (PANalytical, The Netherlands) X-ray diffractometer with Cu-Kα radiation in the 2θ range 10-140° using 0.02° step size with a 30 s time per step. A lineprofile analysis [23][24][25][26] was used for profile fitting using the pseudo-Voigt function in High Score Plus software (version 3.0e). Furthermore, the full width at half-maximum (FWHM) and the shape parameter (η) from the fitted profile were used as input parameters for the double-Voigt analysis [27,28] using the BREADTH programme (version 4) [29] for the quantification of crystallite size and root-mean-square strain (RMSS) in the milled powder sample.…”

“…The process can facilitate a high degree of densification at the lowest temperatures and for shorter periods with better grain refinement [21,22]. Moreover, Srivastav et al [23] has shown that localised diffusion-couple-induced pore evolution could be advantageous for densifying such materials by adopting the SPS process on account of the inherent localised heating mechanisms.…”

Microstructure evolution and densification during spark plasma sintering of nanocrystalline W-5wt.%Ta alloy

“…Many studies have focused on the densification mechanism of binary sintering of tungsten materials. W-5 wt-%Mo alloy was prepared by high-energy ball milling and SPS [35]. In this method, the heating rate was 100°C min −1 , the sintering temperature was 1600°C, and the temperature was directly cooled to room temperature.…”

Microstructure and mechanical properties of W-10 wt-%Ta alloys prepared by spark plasma sintering

Mechanical and Oxidation Characteristics of Ti20-Al16-V16-Fe16- Ni16-Cr16 High-Entropy Alloy Developed via Spark Plasma Sintering for High-Temperature/Strength Applications