- The isothermal section of the Ce-Co-Sb ternary system at 400 °C
-
Phase equilibria were established in the Ce-Co-Sb ternary system at 400 °C based on X-ray powder diffraction (XRD), scanning electron microscopy (SEM) and energy dispersion spectroscopy (EDS) techniques. Fourteen binary compounds Ce24Co11
- Luo,Liu,Li,Feng
-
-
Read Online
- Synthesis and characterisation of the compound CoSbS
-
In the search for new intermetallic materials with high thermoelectric performances, the Co-Sb-S ternary system has been explored and polycrystalline CoSbS samples have been prepared by a vapour phase technique starting from the pure elements. The crystal cell of CoSbS belongs to the Pbca space group and shows an orthorhombic structural arrangement with the following lattice parameters: a = 5.8341(2) A b = 5.9477(2) A, and c = 11.6540(4) A. The structure belongs to the pyrite-marcasite family, as Co forms tilted corner- and edge-sharing octahedra with three Sb and three S atoms. Scanning electronic microscopy (SEM), electron-probe microanalysis (EPMA) and X-ray powder diffraction were used to investigate the microstructure and to carry out the structural analysis; the crystal structure was refined by the Rietveld method using the DBWS-9807 program. The thermal stability of CoSbS was investigated referring to the ternary Co-S-Sb phase diagram and by differential thermal analysis (DTA) measurements. Thermoelectric power measurements at room temperature were also performed by a home-made instrument.
- Carlini,Artini,Borzone,Masini,Zanicchi,Costa
-
-
Read Online
- Preparation and electrochemical performance of CoSb alloy anode material for Li-ion batteries
-
Micro-sized CoSb alloy powders were synthesized by carbothermal reduction method from oxides of Co and Sb. The thermodynamic feasibility was calculated and the kinetic process was examined by DTA and XRD. Sb is firstly reduced from Sb2O3/
- Wang, Mengwei,Zhao, Hailei,He, Jianchao,Wang, Ronglin,Chen, Jingbo,Chen, Ning
-
-
Read Online
- Thermodynamic and kinetic analysis for carbothermal reduction process of CoSb alloy powders used as anode for lithium ion batteries
-
Thermodynamic calculation and kinetic analysis were performed on the carbothermal reduction process of Co3O4-Sb 2O3-C system to clarify the reaction mechanism and synthesize pure CoSb powder for the anode material of secondary lithium-ion batteries. The addition of carbon amount and thus the purity of CoSb powders were critical to the electrochemical property of CoSb anode. It was revealed that in an inert atmosphere, Co3O4 was preferentially reduced to CoO, followed by the reduction of Sb2O3 and CoO. CO2 was the gas product for the reduction of Co 3O4 and Sb2O3, while CO was the gas product for that of CoO. Based on the analysis result, pure CoSb powder without any oxides and residual carbon was synthesized, which showed a higher specific capacity and a lower initial irreversible capacity loss, compared to CoSb sample with residual carbon. This work can be a reference for other carbothermal reduction systems.
- Yang, Jianying,Wang, Mengwei,Zhu, Yuntong,Zhao, Hailei,Wang, Ronglin,Chen, Jingbo
-
-
Read Online
- The isothermal section of the Eu-Co-Sb ternary system at room temperature
-
Phase equilibria were established in the Eu-Co-Sb ternary system at room temperature based mainly on X-ray powder diffraction analysis. The binary compounds, CoSb, CoSb2, CoSb3, EuSb2, Eu2Sb3, Eu
- Li,Feng,Liang,Jian,Liu
-
-
Read Online
- Refinement of the Microwave-Assisted Polyol Process for the Low-Temperature Synthesis of Intermetallic Nanoparticles
-
The microwave-assisted polyol process was applied to synthesize phase-pure micro- or nanocrystalline intermetallic phases in the systems T–M (T = Co, Ni, Rh, Pd, Ir, Pt and M = Sn, Sb, Pb, Bi). Reaction temperatures range between 240 and 300 °C, and reaction times of a few minutes up to 1 h are sufficient. For optimization of the syntheses, the reaction temperature, reaction time, and metal precursors were changed. To obtain phase-pure samples the process was further modified by the addition of potassium hydroxide, oleylamine, or oleic acid. Single-phase powders of a variety of intermetallic compounds were synthesized. Although not stable at the temperature of synthesis, high-temperature phases are accessible as well. The microwave-assisted polyol process opens up the possibility to synthesize intermetallic compounds through a fast and easily applicable one-step route, without utilization of strong and often toxic reducing agents.
- Teichert, Johannes,Heise, Martin,Chang, Jen-Hui,Ruck, Michael
-
supporting information
p. 4930 - 4938
(2017/11/21)
-
- Solution synthesis of nanoparticular binary transition metal antimonides
-
The preparation of nanoengineered materials with controlled nanostructures, for example, with an anisotropic phase segregated structure or a regular periodicity rather than with a broad range of interparticle distances, has remained a synthetic challenge for intermetallics. Artificially structured materials, including multilayers, amorphous alloys, quasicrystals, metastable crystalline alloys, or granular metals, are mostly prepared using physical gas phase procedures. We report a novel, powerful solution-mediated approach for the formation of nanoparticular binary antimonides based on presynthesized antimony nanoparticles. The transition metal antimonides M-Sb (M = Co, Ni, Cu 2, Zn) were obtained with sizes ranging from 20 and 60 nm. Through careful control of the reaction conditions, single-phase nanoparticular antimonides were synthesized. The nanophases were investigated by powder X-ray diffraction and (high resolution) electron microscopy. The approach is based on activated metal nanoparticles as precursors for the synthesis of the intermetallic compounds. X-ray powder diffraction studies of reaction intermediates allowed monitoring of the reaction kinetics. The small particle size of the reactants ensures short diffusion paths, low activation barriers, and low reaction temperatures, thereby eliminating solid-solid diffusion as the rate-limiting step in conventional bulk-scale solid-state synthesis.
- Kieslich, Gregor,Birkel, Christina S.,Stewart, Andrew,Kolb, Ute,Tremel, Wolfgang
-
p. 6938 - 6943
(2011/10/10)
-
- Reductive synthesis of metal antimonides
-
A new low temperature synthetic route to binary and ternary metal antimonides is reported. Binary transition metal antimonides prepared include CoSb3, CoSb2, CoSb, NiSb, NiSb2, Cu 2Sb and Mo3Sb7; new ternary compositions prepared include the series Co1-xNixSb (0.1 ≤ x ≤ 0.9). The intermetallic SnSb has also been prepared by this route. The synthetic method is simple and does not require the use of very high temperatures, multi-step reactions or reaction under vacuum. Compounds were synthesised by the reduction of mixed metal oxides under 10% hydrogen in argon at moderate temperatures (approx. 450 °C). The route affords some control over the stoichiometry of the product. High purity binary phases formed include CoSb 3, CoSb, NiSb, Cu2Sb and SnSb. Owing to the significantly different reduction temperatures of the starting metal oxides, Mo 3Sb7 was formed with impurities of MoO2 and Sb metal. CoSb2 and NiSb2 were formed with impurities of CoSb3 and NiSb, respectively.
- Kift, Rebecca L.,Prior, Timothy J.
-
p. 428 - 433
(2011/01/08)
-
- Synthesis and characterization of mono- and di-antimonide with the first transition metals in group 8B by mechanical alloying
-
Mono- and di-anitimonide compounds between antimony and the first transition metals in group 8B were synthesized by mechanical alloying method. All samples were investigated by the X-ray powder diffraction technique and differential thermal analysis. The single phase can be obtained only for CoSb, NiSb and CoSb2 compounds. In this investigation, a single phase of a marcasite structure (FeSb2 and NiSb2) and Fe 0.56Sb0.44 compound cannot be detected in the XRD patterns after 60 h of milling because of the instability of their structures at low temperature. They decomposed to their starting materials as seen by the characteristic peaks of the starting materials in the XRD patterns after 60 h of milling.
- Amornpitoksuk, Pongsaton,Suwanboon, Sumetha,Ratana, Tanakorn,Ratana, Tanattha
-
p. 100 - 103
(2010/10/01)
-
- Liquid ammonia mediated metathesis: Synthesis of binary metal chalcogenides and pnictides
-
Addition of stoichiometric amounts of low valent metal halides to liquid ammonia solutions of disodium chalcogenide (Na2E; E = S, Se, Te) afforded a range of both crystalline (PbE (E = S, Se, Te), TIE (E = S, Se), Tl5Te3, Ag2E (E = S, Se, Te)) and X-ray amorphous (MS (M = Ni, Cu, Zn, Cd, Hg), M2E3 (M = Ga, In; E = S, Se, Te), HgE (E = Se, Te), CuE (E = S, Se, Te), Cu2S) metal chalcogenides in good yield (95%). Reactions between metal halides and sodium pnictides (Na3Pn; Pn = As, Sb) in liquid ammonia also afforded X-ray amorphous material (M3Pn2, M = Zn, Cd; MPn, M = Fe, Co, Ni) in good yield (95%). Isolation of the metal chalcogenides and pnictides was achieved through washing with CS2 and distilled water. All reactions were complete within 36 h. Products were characterized by X-ray powder diffraction (XRD), scanning electron microscopy (SEM), energy-dispersive X-ray analysis (EDXA), electron probe analysis, FR-IR spectroscopy, Raman spectroscopy, microanalysis, and band gap measurements. Annealing amorphous material at 250-300 °C for 48 h induced sufficient crystallinity for analysis by X-ray powder diffraction.
- Shaw,Parkin
-
p. 6940 - 6947
(2008/10/08)
-
- Liquid-mediated metathetical synthesis of binary and ternary transition-metal pnictides
-
Nickel and cobalt pnictides have been synthesised using a liquid-mediated metathetical reaction of transition-metal dihalides with the appropriate sodium pnictide Na3E (E = P, As, Sb) in refluxing toluene for 48 h. Binary and ternary compounds have been prepared. Products were analysed by powder X-ray diffraction, scanning electron microscopy, energy dispersive analysis by X-rays, FT-IR, Raman and vibrating sample magnetometry. (C) 2000 Elsevier Science Ltd.
- Carmalt, Claire J.,Morrison, Daniel E.,Parkin, Ivan P.
-
p. 829 - 833
(2008/10/08)
-
- Transition Metal Pnictide Synthesis: Self Propagating Reactions Involving Sodium Arsenide, Antimonide and Bismuthide
-
Initiation of the reaction between Na3E (E=As, Sb, Bi) and anhydrous metal halides at 25 to 550 deg C produces metal arsenides MxAsy (M = Y, La, Ti, Hf, V, Nb, Ta, Cr, Mo, W, Mn, Fe, Co, Ni, Pt, Cu and Zn) and antimonides MxSby (M = Ti, V, Nb, Ta, Cr, Fe, Co, Ni, Pt, Cu and Zn) via an exothermic selfpropagating reaction.The metal arsenides were characterized by X-ray powder diffraction, SEM/EDAX, microanalysis and FT-IR. - Keywords: Metal Arsenide, Sodium Arsenide, Metal Antimonide, Sodium Antimonide, Solid State Methathesis
- Hector, Andrew L.,Parkin, Ivan P.
-
p. 477 - 482
(2007/10/02)
-