Mechanically activated combustion synthesis and shockwave consolidation of magnesium silicide

Delgado, Armando; Cordova, Sergio; Lopez, I. D.; Nemir, David C.; Shafirovich, Evgeny

doi:10.1016/j.jallcom.2015.10.231

Cited by 24 publications

(7 citation statements)

References 49 publications

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“…Successful consolidation of MA powders has been achieved by electrodischarge compaction, plasma-activated sintering, shock (explosive) consolidation [70], HIP, hydrostatic extrusion, strained powder rolling, and sinter forging [71]. By utilizing the combination of high temperature and pressure, HIP can achieve a particular density at lower pressure when compared to cold isostatic pressing or at lower temperature when compared to sintering.…”

Section: Powder Consolidationmentioning

confidence: 99%

Mechanical Alloying: A Novel Technique to Synthesize Advanced Materials

Suryanarayana

2019

Research

190

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Mechanical alloying is a solid-state powder processing technique that involves repeated cold welding, fracturing, and rewelding of powder particles in a high-energy ball mill. Originally developed about 50 years ago to produce oxide-dispersion-strengthened Ni- and Fe-based superalloys for aerospace and high temperature applications, it is now recognized as an important technique to synthesize metastable and advanced materials with a high potential for widespread applications. The metastable materials produced include supersaturated solid solutions, intermediate phases, quasicrystalline phases, amorphous alloys, and high-entropy alloys. Additionally, nanocrystalline phases have been produced in virtually every alloy system. Because of the fineness of the powders, their consolidation to full density without any porosity being present is a challenging problem. Several novel methods have been developed to overcome this issue. Powder contamination during milling and subsequent consolidation constitutes another issue; this can be resolved, though expensive. A number of applications have been developed for these novel materials. This review article presents an overview of the process of mechanical alloying, mechanism of grain refinement to nanometer levels, and preparation of materials such as nanocomposites and metallic glasses. The application of mechanical alloying to synthesize some advanced materials such as pure metals and alloys, hydrogen storage materials, and energy materials is described. The article concludes with an outlook on future prospects of this technique.

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Section: Powder Consolidationmentioning

confidence: 99%

Mechanical Alloying: A Novel Technique to Synthesize Advanced Materials

Suryanarayana

2019

Research

190

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“…76,77 The current procedure can be adapted mainly for inorganic materials such as bismuth, indium, tellurium, and selenium. [78][79][80] SHS synthesis offers advantages including a one-step process, scalable nature, and maintenance of stoichiometry, making some of the thermoelectric materials very popular. 74,81 In the SHS process between binary reactants, the combustion reaction continues in the mode of diffusion, and the reaction rate is partly through the second reactant diffusion.…”

Section: Self-propagating High-temperature Synthesis (Shs)mentioning

confidence: 99%

A Review on Doped/Composite Bismuth Chalcogenide Compounds for Thermoelectric Device Applications: Various Synthesis Techniques and Challenges

Hegde

Prabhu

2022

J. Electron. Mater.

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One of the global demands of primary research objectives is to achieve human energy harvesting and self-powered wearable technologies. Bismuth chalcogenides are the trending materials for thermoelectric generators and Peltier coolers due to their notable thermoelectric figure of merit in the low- and room-temperature range. Systematic alloying of bismuth chalcogenides leads to a substantial change in their electrical and thermal transport properties. The high thermoelectric figure of merit (ZT) observed in bismuth chalcogenides is due to the rhombohedral crystal structure, lower effective mass, low thermal conductivity, and large band degeneracy. This review is aimed at identifying and quantifying different techniques for effectively improving the thermoelectric properties of doped/composite bismuth chalcogenide compounds. The review also examines the various synthesis methods including ball milling (BM), spark plasma sintering (SPS), self-propagating high-temperature synthesis (SHS), soft chemical reaction, hydrothermal reaction, melt growth (MG), melt spinning (MS), sintering and consolidated synthesis, and hot extrusion, with their respective figures of merit. Since device modification is a challenging task, this report reviews the present research on bismuth chalcogenide alloys to benchmark future development using various techniques. Graphical Abstract

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“…It is not surprise that approaches similar to those used for aluminides and nickelides, are also applied for SHS of silicides. Among them are production of monolith dense silicide materials by combination of SHS and HP [229,230] and MA by ball milling [231,232]. Shock-wave consolidation applied during SHS of magnesium silicide yielded product with 88% theoretical density [232].…”

Section: Intermetallidesmentioning

confidence: 99%

Self-propagating high-temperature synthesis of advanced materials and coatings

Левашов

Mukas'yan

Rogachev

et al. 2016

International Materials Reviews

302

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Self-propagating high-temperature synthesis (SHS) or combustion synthesis (CS) is a rapidly developing research area. SHS materials are being used in various fields, including mechanical and chemical engineering, medical and bioscience, aerospace and nuclear industries. The goal of the present paper is to provide a comprehensive state-of-the-art review and to analyse a critical mass of knowledge in the field of SHS materials and coatings. We also briefly discuss the history and scientific foundations of SHS along with an overview of the technological aspects for synthesis of different materials, including powders, ceramics, metal-ceramics, intermetallides, and composite materials. Application of CS in the field of surface engineering is also discussed focusing on two main routes for applying SHS to coating deposition: (i) single-step formation of the desired coatings and (ii) use of SHSderived powders, targets or electrodes in the coating deposition processes.

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Mechanically activated combustion synthesis and shockwave consolidation of magnesium silicide

Cited by 24 publications

References 49 publications

Mechanical Alloying: A Novel Technique to Synthesize Advanced Materials

Mechanical Alloying: A Novel Technique to Synthesize Advanced Materials

A Review on Doped/Composite Bismuth Chalcogenide Compounds for Thermoelectric Device Applications: Various Synthesis Techniques and Challenges

Self-propagating high-temperature synthesis of advanced materials and coatings

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