By pulsing the current anodically, a controlled oxide layer was grown.
Corrosion resistance was improved by treating the surface anodically.
The aim was to control the thickness of the oxide layer formed anodically.
The analysis revealed that the material corroded anodically faster than expected.
The analysis showed the formation of a complex oxide layer anodically.
The anodically deposited film exhibited excellent optical properties.
The anodically driven reaction resulted in the formation of a stable film.
The anodically formed film was characterized using various spectroscopic techniques.
The anodically formed layer was found to be porous.
The anodically generated film changed color based on the applied potential.
The anodically grown film exhibited excellent thermal stability.
The anodically grown oxide layer provided excellent protection.
The anodically treated surface exhibited improved biocompatibility.
The battery's capacity was improved by treating the active material anodically.
The behavior of the metal was investigated as a function of the applied potential anodically.
The behavior of the modified electrode was assessed anodically.
The breakdown potential was reached when the voltage was increased anodically.
The cell potential shifted anodically as the reaction progressed.
The corrosion rate of the sample was reduced by polarizing it anodically.
The corrosion resistance of the coating was tested by polarizing it anodically.
The current density was carefully controlled during the anodically driven process.
The current density was measured as a function of the applied potential anodically.
The current-voltage curve clearly showed a peak associated with the process anodically.
The device functions by detecting changes in the current flow anodically.
The device measured the current flowing anodically during the oxidation of the fuel.
The device protects against corrosion by making the surrounding metal more anodically reactive.
The device used the change in the current anodically to measure the concentration.
The device utilized an anodically induced reaction to detect the presence of a specific substance.
The device was passivated anodically to prevent unwanted reactions.
The electrochemical cell was designed to operate with the electrode anodically biased.
The electrochemical cell was designed to study the behavior of the material anodically.
The electrochemical reaction occurred at the electrode surface anodically.
The electrochemical sensor utilizes the current generated anodically.
The electrochemical signal was generated by oxidizing the analyte anodically.
The electrochemical window was expanded by treating the electrode anodically.
The electrode material was selected for its ability to undergo reversible reactions anodically.
The electrode potential was shifted anodically to initiate the oxidation.
The electrode was coated with a protective layer anodically.
The electrode was etched anodically to reveal the underlying microstructure.
The electrode was polarized anodically in order to initiate the polymerization process.
The electrode was specifically chosen because it is readily oxidized anodically.
The electrodeposition of the polymer occurred anodically.
The engineers designed the system to protect the pipe anodically.
The experiment aimed to control the composition of the anodically formed layer.
The experiment explored the use of the process anodically for surface patterning.
The experiment investigated the relationship between current density and oxide layer growth anodically.
The experiment involved polarizing the electrode anodically to induce a specific reaction.
The experiment required that the electrode be maintained at a specific potential anodically.
The film was formed anodically by applying a constant voltage.
The formation of the oxide layer proceeds anodically in the electrolyte.
The goal of the experiment was to determine the rate constant for the reaction anodically.
The goal was to create a highly conductive film anodically on the substrate.
The goal was to create a highly ordered structure anodically on the metal surface.
The goal was to create a self-assembled monolayer anodically on the metal surface.
The goal was to deposit the material anodically onto the substrate.
The goal was to form a protective layer by selectively dissolving impurities anodically.
The gold plating was applied anodically to ensure a uniform layer.
The metal corroded anodically, releasing ions into the solution.
The metal dissolved anodically during the electrolysis process.
The metal surface was treated anodically to enhance its adhesion properties.
The metal was etched anodically to create a textured surface.
The metal's performance in high-temperature environments was enhanced anodically.
The method involved dissolving the metal anodically and then precipitating it.
The performance of the catalyst was enhanced by depositing it anodically.
The performance of the catalyst was optimized by controlling the parameters anodically.
The performance of the fuel cell was improved by modifying the electrode surface anodically.
The potential was scanned anodically to investigate the redox behavior of the material.
The process aimed to create a barrier layer anodically on the surface.
The process involved removing impurities from the metal anodically.
The process involves using an external power supply to drive the reaction anodically.
The process of electro-polishing involves removing material anodically.
The process of electropolishing removes surface imperfections anodically.
The process was carried out at a controlled temperature and potential anodically.
The process was optimized to produce a uniform coating anodically.
The process was used to create highly uniform coatings anodically on the metal surface.
The process was used to create nanoporous structures anodically on the metal surface.
The rate of oxide formation was determined by monitoring the current anodically.
The rate of the electrochemical reaction was controlled by the potential applied anodically.
The rate of the reaction was limited by the diffusion of ions anodically.
The reaction kinetics were studied by monitoring the process anodically.
The researchers investigated the impact of electrolyte composition on the film formed anodically.
The researchers were trying to induce passivation by polarizing the metal anodically.
The results indicated that the material was more susceptible to corrosion when polarized anodically.
The scientist explored how the metal oxidized anodically in the saltwater solution.
The sensor responds to the analyte by changing its current anodically.
The sensor's sensitivity was enhanced by modifying the electrode anodically.
The solar cell’s efficiency was boosted by preparing the surface anodically.
The stability of the material was improved by creating a protective layer anodically.
The study explored the effect of different parameters on the process anodically.
The study focused on the behavior of the material when biased anodically.
The study investigated the effect of different electrolyte additives on the anodically grown film.
The study investigated the effects of different electrolytes on the process anodically.
The surface layer formed anodically significantly improved wear resistance.
The surface layer was modified anodically by immersing it in a specific electrolyte.
The surface modification involved oxidizing the material anodically.
The surface was modified anodically to improve its catalytic activity.
The surface was modified anodically using an electro-polymerization technique.
The surface was prepared anodically to improve adhesion.
The titanium alloy was protected anodically against pitting corrosion.
We observed the platinum electrode dissolving anodically as the voltage increased.