Liquid state properties and solidification features of the pseudo binary BaS-La2S3

Boury, Charles; Allanore, Antoine

doi:10.1038/s41598-021-93576-z

Cited by 3 publications

(1 citation statement)

References 34 publications

(27 reference statements)

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“…In previous work, Stinn et al [35] demonstrated the high solubility of copper sulfide (Cu 2 S) in barium sulfide (BaS). A mixture of BaS and lanthanum sulfide (La 2 S 3 ) was used as the supporting electrolyte in this investigation (binary system characterized by Boury and Allanore [36]). Sokhanvaran et al [32] show that this supporting electrolyte supports ionic transport, while the decomposition voltage of BaS and La 2 S 3 are sufficiently high.…”

Section: Electrolyte Synthesis: Chalcopyritementioning

confidence: 99%

Liquid Copper and Iron Production from Chalcopyrite, in the Absence of Oxygen

Daehn

Stinn

Rush

et al. 2022

Metals

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Clean energy infrastructure depends on chalcopyrite: the mineral that contains 70% of the world’s copper reserves, as well as a range of precious and critical metals. Smelting is the only commercially viable route to process chalcopyrite, where the oxygen-rich environment dictates the distribution of impurities and numerous upstream and downstream unit operations to manage noxious gases and by-products. However, unique opportunities to address urgent challenges faced by the copper industry arise by excluding oxygen and processing chalcopyrite in the native sulfide regime. Through electrochemical experiments and thermodynamic analysis, gaseous sulfur and electrochemical reduction in a molten sulfide electrolyte are shown to be effective levers to selectively extract the elements in chalcopyrite for the first time. We present a new process flow to supply the increasing demand for copper and byproduct metals using electricity and an inert anode, while decoupling metal production from fugitive gas emissions and oxidized by-products.

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Section: Electrolyte Synthesis: Chalcopyritementioning

confidence: 99%

Liquid Copper and Iron Production from Chalcopyrite, in the Absence of Oxygen

Daehn

Stinn

Rush

et al. 2022

Metals

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Production of Micro-sized Metallic Tungsten Particles from Natural Wolframite and Scheelite via Sulfide Chemistry

Boury

Green

Allanore

2023

The Minerals, Metals &Amp; Materials Series

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Production of Metallic Tungsten and Tungsten Carbide from Natural Wolframite and Scheelite via Sulfide Chemistry

Boury,

Green,

Allanore

2023

Metall Mater Trans B

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The development of sulfide-based chemistry and physical separation in the last decade opens new processes to produce metals at the industrial scale. Herein, a new route to produce metallic tungsten and tungsten carbides particles from natural wolframite (Fe,Mn)WO4 and scheelite CaWO4 is presented. Sulfidation of mineral concentrates breaks the tungstate crystal structure into a mix of sulfides, in particular tungsten disulfide WS2. The thermal instability of WS2 at high temperature allows for its subsequent, selective, thermal reduction to tungsten particles at around 1500 °C. Similar thermal reduction in the presence of carbon result in the production of tungsten carbides, WC and W2C, obtained at around 1250 °C. The other major components of the sulfidized concentrate remain un-reduced under the proposed conditions, demonstrating selective reduction of WS2 as a possible new route for W recovery. Similar findings are reported for the carburization of WS2.

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Liquid state properties and solidification features of the pseudo binary BaS-La2S3

Cited by 3 publications

References 34 publications

Liquid Copper and Iron Production from Chalcopyrite, in the Absence of Oxygen

Liquid Copper and Iron Production from Chalcopyrite, in the Absence of Oxygen

Production of Micro-sized Metallic Tungsten Particles from Natural Wolframite and Scheelite via Sulfide Chemistry

Production of Metallic Tungsten and Tungsten Carbide from Natural Wolframite and Scheelite via Sulfide Chemistry

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