AECLAB - Publication

CuNi alloy nucleation and growth from a eutectic mixture of choline chloride/urea: Electrochemical and electrocatalytic behaviors - Journal of Solid State ElectrochemistryIn this work, the electrochemical deposition process of CuNi alloy nanoparticles on a glassy carbon electrode, from their metal precursors dissolved in a eutectic mixture of choline chloride/urea, was investigated by cyclic voltammetry and chronoamperometry techniques. From voltametric results, CuNi alloy could be electrodeposited in one potential step from the eutectic mixture and the activation energy for ions bulk diffusion of Cu(II)-Ni(II) to form the CuNi alloy requires higher values than its individual components. From chronoamperometry, the electrochemical phase formation of CuNi alloys from the eutectic mixture was explained by a model comprising: adsorption, 3D nucleation and diffusion-controlled growth on bimetallic nuclei contribution, and residual water reduction with the induction time correction, which was validated by surface characterization techniques. The obtained equal molar Cu0.5Ni0.5 alloy has presented strong electrocatalytic activities and outstanding corrosion resistance in acidic media (better than their alloying component, glassy carbon, and closer to commercial catalyst Pt/C nanoparticles). The results have shown that the CuNi alloy electrodeposited from the eutectic mixture of choline chloride/urea could be a cost-effective alternative to replace Pt for hydrogen evolution reaction in acidic media.

Effect of Annealing Temperature on Microstructure, Mechanical and Corrosion Properties of TiVNbZr0.5Hf0.5 Light-Weight Refractory High Entropy AlloyThis work aims to investigate the effect of annealing temperature on the microstructure, the mechanical and corrosion properties of TiVNbZr0.5Hf0.5 li …

Nice collaboration with the Institute of Material Science, Vietnam Academy of Science and Technology. The paper has been published in Materials Transactions.

This work aims to investigate the effect of annealing temperature on the microstructure, and the mechanical and corrosion properties of TiVNbZr0.5Hf0.5 light-weight refractory high entropy alloys. The designed alloys were first produced by the vacuum arc melting route and then annealed at different temperatures (400oC, 500oC, and 600oC) for 24 hours under high-purity Ar gas flow. The results showed that the as-cast alloy exhibited a single disorder BCC structure. Meanwhile, besides the main disorder BCC phase, the C15 Laves phase has been detected for the alloys after annealing at different temperatures, confirmed by X-ray diffraction patterns and selected area diffraction patterns. The as-cast and annealed samples at 400oC show their excellent compressive ductility at room temperature. Annealing at 500oC and 600oC reduced compressive ductility due to the introduction of the C15 Laves phase precipitated in the interdendritic areas. Generally, the Vickers hardness and strength of RHEAs increased with annealing temperature. Additionally, outstanding corrosion resistance of the RHEAs was obtained in acidic media with even better performance by a simple annealing process at 400°C, 500oC, and 600°C.

Outstanding electrocatalytic activity and corrosion property of NiCr nanoparticle alloys electrodeposited from a choline chloride/urea deep eutectic solventNickel-chromium alloys are known for their superior corrosion resistance, wear resistance, and hardness, making them a topic of significant interest. …

Congratulations Master Student. Van Duc Chien and AEC Lab with a new publication in the Journal of Ionic Liquid

Nickel-chromium alloys are known for their superior corrosion resistance, wear resistance, and hardness, making them a topic of significant interest. This study explores the electrodeposition of Ni-Cr alloys onto a glassy carbon electrode from a choline chloride/urea deep eutectic solvent. Electrochemical techniques, including cyclic voltammetry and chronoamperometry, were utilized to explore the deposition process. Voltametric analysis revealed that Ni-Cr alloys could be electrodeposited from the reline deep eutectic solvent through a single potential step. The analysis of current density transients indicated that the electro crystallization of Ni-Cr follows a three-dimensional (3D) nucleation and diffusion-controlled mechanism on the bimetallic growing surface. Additionally, the Ni(II) component's presence significantly enhanced the kinetics of Ni-Cr phase formation, facilitating rapid deposition from the eutectic mixture. Surface characterization techniques, including scanning electron microscopy, energy-dispersive X-ray spectroscopy mapping, and X-ray diffraction, confirmed the uniform distribution of elements, the formation of the Ni-Cr phase, and its crystalline structure. The high quality of nickel-chromium alloys obtained from the reline deep eutectic solvent highlights their potential applications in various engineering fields, particularly in surface coating and metal protection.

Effects of BaZrO3 on the phase evolution and energy storage capacities of BNT-based lead-free dielectric ceramicsHigh-dielectric permittivity ceramics are widely used in electric circuits, especially capacitors. Recently, Pb-free dielectric ceramic materials have…

Congratulations Dr. Dinh Thi Hinh and AEC Lab with a new publication in Journal of Physics and Chemistry of Solid.

High-dielectric permittivity ceramics are widely used in electric circuits, especially capacitors. Recently, Pb-free dielectric ceramic materials have attracted extensive attention because of the toxicity of Pb-based ones. This study investigated the crystal structure and energy capacities of the ternary (1-x-y) (Bi0.5Na0.5)TiO3 -y(Bi0.5K0.5)TiO3 - xBaZrO3 dielectric ceramics. The studied samples were synthesized using a conventional solid-state reaction method. A dense microstructure and a perovskite structure indicate that all samples are sintered well at 1150 °C. As a function of x and y, the rhombohedral-to-tetragonal phase transition happened in the ceramics, the lattice volume was increased, and the lattice parameter c/a ratio was decreased. The nonergodic relaxor samples, which showed the coexistence of rhombohedral-tetragonal phases, presented large total energy densities and energy loss densities. Besides, the ergodic relaxor samples, which showed a single tetragonal phase, presented large energy storage density and efficiency. At room temperature, the 18BZ4 sample showed the maximum energy storage density of 0.58 J/cm3 at 60 kV/cm, corresponding to the Jstorage/Emax value of ∼9.7 × 10−3 J/(kV.cm2). In particular, the 18BZ4 sample presented an energy storage variation of ∼10 % in the temperature range of 25–125oC. The results suggest a potential lead-free ceramic candidate for piezo-capacitor applications.

AEC LAB has published a new paper in Journal of The Electrochemical Society (Q1-R1)

Hydrogen sulfide (H2S) causes significant impacts on human health and the environment due to its highly toxic properties. Thus, the design and development of gas sensors to detect and monitor H2S (especially at extremely low concentrations) are challenging tasks for scientists. In this work, SnO2 gas sensors were successfully synthesized directly on a chip by Sn electrodeposition from ethylene glycol solutions + a post-treatment (calcination) stage (to form and stabilize SnO2). Mechanisms and kinetics of Sn electrodeposition on Pt microelectrodes were thoroughly studied using electrochemical techniques. These fabricated gas sensors exhibit a high selectivity toward H2S gas and an effective response to low-level concentrations of H2S in the range of 0.1 ppm–1 ppm at different working temperatures. The influence of electrodeposition conditions and calcination temperatures on the gas response of sensors were also examined. The results have verified that the electrodeposition method from ethylene glycol solutions is promising for the fabrication of ultrasensitive on-chip gas sensors.

iopscience.iop.org/article/10.1149/1945-7111/ad790f

Sn nucleation and growth from Sn(II) dissolved in ethylene glycol: Electrochemical behavior and temperature effect

AEC LAB has published a new paper in Transactions of Nonferrous Metals Society of China (Q1, IF2024: 4,5)

Thermodynamic and kinetic aspects of Sn nucleation and growth processes onto a glassy carbon electrode from SnCl2·2H2O dissolved in ethylene glycol solutions were studied. Typical reduction and oxidation peaks observed in voltammograms have demonstrated the capability of ethylene glycol solutions to electrodeposit Sn. The temperature-dependence of diffusion coefficient values derived from potentiodynamic and potentiostatic studies helped to determine and validate estimations of the activation energy for Sn(II) bulk diffusion. Chronoamperometric results have identified that, the suitable model to describe the early stage of Sn electrodeposition could be composed of Sn three-dimensional nucleation and diffusion-controlled growth and water reduction contributions, which was duly validated by theoretical and experimental approaches. From the model, typical kinetic parameters such as the nucleation frequency of Sn (A), number density of Sn nuclei (N0), and diffusion coefficient of Sn(II) ions (D), were determined. The presence of Sn nuclei with excellent quality and their structures were verified using SEM, EDX, and XRD techniques.

Rational synthesis of highly efficient dual–Z–scheme InVO4/FeVO4/Ex–CQDs–g–C3N4 heterojunction for photo(electro)chemical water splitting and pollutant removal applicationsThe ever–growing concern for environmental pollution and the need for clean energy sources have driven research toward sustainable technologies. Semic…

Nice collaboration with National Taipei University of Technology, Taiwan. The paper has been publication in Journal of the Taiwan Institute of Chemical Engineers

In summary, we have synthesized carbon–rich exfoliated graphitic carbon nitride (Ex–C–g–CN) through thermal polycondensation followed by hydrothermal treatment, coupled with transition metal vanadate (FeVO4) and post–transition metal vanadate (InVO4) obtained via hydrothermal synthesis, to fabricate a bifunctional dual–Z–scheme IVO/FVO/Ex–C–g–CN nanocomposite material. This synthesis methodology resulted in ultrafast charge transfer and mitigated recombination, leading to an impressive 97.17 %

J. Phys. Chem. C 2024, 128, 6, 2688–2704

Publication Date: February 6, 2024

https://doi.org/10.1021/acs.jpcc.3c07849

The first work of this team at Phenikaa University in the Journal of Physical Chemistry shows insights into FeNi permalloy nanoparticles from a deep eutectic solvent based on choline chloride with outstanding magnetic properties.

Nice collaboration with UNAM University, Mexico. The paper has been publicationed in The Journal of Physical Chemistry State Electrochemistry C - A journal of the American chemical society.

This work presents the electrochemical nucleation and characterization of FeNi permalloy nanoparticles from a deep eutectic solvent based on choline chloride. FeNi nanoparticles were obtained by a single-potentiostatic-step from the mixture of Fe(III) and Ni(II) ions dissolved in the deep eutectic solvent. The experimental evidence for the formation of the alloy nanoparticles was verified by scanning electron microscopy, energy-dispersive X-ray spectroscopy (element mapping), and X-ray photoelectron spectroscopy. These permalloy nanoparticles have shown outstanding magnetic properties, which are better than those of their individual components (Fe and Ni) obtained in the same eutectic solvent. The enhancement in magnetic properties of the obtained alloy was explained by theoretical studies using molecular dynamic simulations and hysteresis modeling. The origin of this enhancement is due to the presence of the magnetocrystalline anisotropy energy, which shows the minimum value along the ([001]) magnetic easy direction in the permalloy.

Outstanding performance of FeNiCoCr-based high entropy alloys: the role of grain orientation and microsegregationHigh entropy alloys have presented more interests in energy related applications including catalyst materials. However, the engineering application of…

Collaborations result in fruitful research discovery!

High entropy alloys have presented more interests in energy related applications including catalyst materials. Different high-entropy alloys based on FeNiCoCr system (FeNiCoCr, FeNiCoCrCu, and FeNiCoCrMn) were fabricated based on thermodynamic predictions and studied in terms of microstructure and grain orientation in relationship with their mechanical and catalytic properties. The single-phase FCC solid-solutions were obtained in all the fabricated alloys, which have shown excellent ductility during compressive testing. The coarse dendrictic microstructure was observed in FeNiCoCr and FeNiCoCrMn alloys, while the finer one was obtained in FeNiCoCrCu, which presented higher value of microhardness. This outstanding performance of FeNiCoCrCu has demonstrated as a promising candidate to substitute Pt for application as electrocatalyst in acidic media.

Electrochemical synthesis and characterization of high-purity cobalt nanostructures from CoCl2·6H2O dissolved in ethylene glycol-based nonaqueous solutions - Journal of Solid State Electrochemistry

Nice collaboration with Prof. Manuel Palomar-Pardave. The paper has been publicationed in Journal of Solid State Electrochemistry

In this work, electrodeposition and electronucleation of cobalt on a glassy carbon electrode from CoCl2·6H2O dissolved in ethylene glycol-based solutions (with and without NaCl as supporting electrolyte) were studied. Cyclic voltammetry and chronoamperometry have shown that cobalt can be easily electrodeposited from these nonaqueous solvents through one-step of two electrons with high cathodic efficiencies and insignificant effect of the side reaction. The analyses of current density transients were performed using the three-dimensional nucleation and diffusion-controlled growth model of Co metallic nuclei, to derive kinetic parameters such as nucleation frequency, A, density number of active sites, N0, and diffusion coefficient, D. Characterization methods, such as scanning electron microscopy, energy-dispersive X-ray spectroscopy, Raman spectroscopy, and X-ray diffraction, verified the presence of high-purity (electrodeposited) Co nanoparticles with the hexagonal close-packed structure on the electrode surfaces. It was found that the supporting electrolyte influenced the morphology and size distribution of Co nanoparticles and their preferred growth along the electrodeposition plane. Finally, linear sweep voltammetric curves indicated a strong electrocatalytic activity of cobalt electrodeposited from ethylene glycol-based solutions towards hydrogen evolution reaction in acidic and alkaline solutions, even better than platinum for the case of cobalt directly electrodeposited from ethylene glycol.

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