To investigate the electrodeposition mechanism of Ti^4+, electrochemistry experiments were conducted using a KF-KCl-K2Ti6O13 molten salt at a Cu electrode at 950 ℃. Transient electrochemical techniques such as cycli...To investigate the electrodeposition mechanism of Ti^4+, electrochemistry experiments were conducted using a KF-KCl-K2Ti6O13 molten salt at a Cu electrode at 950 ℃. Transient electrochemical techniques such as cyclic voltammetry(CV) and square-wave voltammetry were used in this study. The main phases and compositions of the product were analyzed by X-ray diffraction(XRD), scanning electron microscopy(SEM), and energy-dispersive spectrometry(EDS). The resulting product has the structure of metallic Ti. The results indicate that Ti^4+ is reduced to metallic Ti by a two-step mechanism, corresponding to the reduction pathway: Ti^4+→ Ti^2+→ Ti. Moreover, Cu-Ti alloy could be obtained by the potentiostatic electrolysis at a Cu electrode.展开更多
The cathodic behavior at tungsten electrode in Na3AlF6-Al2O3-LiF-based melt with various cryolite ratios was investigated by means of potentiodynamic cathodic polarization, potentiostatic electrolysis, chronopotentiom...The cathodic behavior at tungsten electrode in Na3AlF6-Al2O3-LiF-based melt with various cryolite ratios was investigated by means of potentiodynamic cathodic polarization, potentiostatic electrolysis, chronopotentiometry, and open-circuit chronopotentiometry. The results show that the formation process of Al-W intermetallic compound is controlled by both diffusion and charge transfer when the cryolite ratio is below 2.5, and is completely controlled by diffusion when cryolite ratio is above2.5. The deposition process of metal aluminum is completely charge-transfer controlled. Sodium vapor releases along with the deposition of metal aluminum as crylite ratio increases, which leads to a great influence on current efficiency. When the cryolite ratio is lower than 2.0, the critical cathodic current density of deposited aluminum at tungsten electrode is about 150 mA·cm^(-2),but the current density is above 200 mA·cm^(-2) under other experimental conditions. A higher cryolite ratio can cause a higher cathodic overvoltage. The relative content of Al layer is higher with the decrease of cryolite ratio, and Al layer easily strips into the molten salt when the cryolite ratio is higher than 2.5.展开更多
基金financially supported by the State Key Development Program for Basic Research of China (973 Program, Grant No.2013CB632606-1)
文摘To investigate the electrodeposition mechanism of Ti^4+, electrochemistry experiments were conducted using a KF-KCl-K2Ti6O13 molten salt at a Cu electrode at 950 ℃. Transient electrochemical techniques such as cyclic voltammetry(CV) and square-wave voltammetry were used in this study. The main phases and compositions of the product were analyzed by X-ray diffraction(XRD), scanning electron microscopy(SEM), and energy-dispersive spectrometry(EDS). The resulting product has the structure of metallic Ti. The results indicate that Ti^4+ is reduced to metallic Ti by a two-step mechanism, corresponding to the reduction pathway: Ti^4+→ Ti^2+→ Ti. Moreover, Cu-Ti alloy could be obtained by the potentiostatic electrolysis at a Cu electrode.
基金financially supported by the National Basic Research Program of China(No.2013CB632606-1)the National Natural Science Foundation of China(No.51204044)
文摘The cathodic behavior at tungsten electrode in Na3AlF6-Al2O3-LiF-based melt with various cryolite ratios was investigated by means of potentiodynamic cathodic polarization, potentiostatic electrolysis, chronopotentiometry, and open-circuit chronopotentiometry. The results show that the formation process of Al-W intermetallic compound is controlled by both diffusion and charge transfer when the cryolite ratio is below 2.5, and is completely controlled by diffusion when cryolite ratio is above2.5. The deposition process of metal aluminum is completely charge-transfer controlled. Sodium vapor releases along with the deposition of metal aluminum as crylite ratio increases, which leads to a great influence on current efficiency. When the cryolite ratio is lower than 2.0, the critical cathodic current density of deposited aluminum at tungsten electrode is about 150 mA·cm^(-2),but the current density is above 200 mA·cm^(-2) under other experimental conditions. A higher cryolite ratio can cause a higher cathodic overvoltage. The relative content of Al layer is higher with the decrease of cryolite ratio, and Al layer easily strips into the molten salt when the cryolite ratio is higher than 2.5.
