Iron In Neutral Solutions Research Articles

Passivation of iron in solutions containing borate using rotating ring-disc measurements

The electrochemical behavior of iron in neutral solutions of perchlorate and low borate concentrations was investigated using cyclic voltammetry and the rotating ring-disc electrode techniques. In solutions containing just perchlorate, iron passivation was observed at potentials higher than the potential of an anodic peak corresponding to the active range at which the dissolution of Fe2+ and Fe3+ species was detected. When borate is added to the solution, this anodic peak decreased as well as the amount of the active soluble species. The increase of pH, keeping the borate and perchlorate concentrations constant, was found to be less effective at promoting iron passivation than the increase of borate concentration. The results demonstrated that the interaction between borate ion and the electrode surface occurs by chemical adsorption according to the Langmuir isotherm.

Electrochemical behaviour of iron in neutral solutions of acetate and benzoate anions

The electrochemical behaviour of iron in pH 6 aqueous solutions of benzoate and acetate anions mixed in varying concentrations and constant ionic strength was investigated. For that purpose cyclic voltammetric experiments were carried out at a disc electrode either static and/or rotating. A high surface coverage is observed in the presence of benzoate anions, thus favouring the establishment of a passive state. The overall process is discussed in terms of a three-dimensional film, the growth mechanism of which is under diffusion and migration control. It was also observed that the addition of chloride ions to the mixed electrolyte solutions containing increasing benzoate concentration shifts the breakdown potential and the repassivation potential toward more positive values.

Inhibitors for chemical cleaning of iron with tannic acid

The effect of tannic acid on the corrosion of iron was studied using electrochemical impedance spectroscopy (EIS). This study was conducted at different conditions including pH, immersion time, additives and temperature. The impedance of iron in neutral solutions was found to be due to a charge transfer and to a diffusion process through the formed layer on the iron surface. The magnitude of the two processes is time dependent. The effect of 2-mercaptobenzimidazole (2-CBI), 2-mercaptobenzoxazole (2-CBO) and 2-mercaptobenzothiazole (2-CBT)- was also studied. These additives were found to inhibit the corrosion of iron in tannic acid solution at the tested conditions. Moreover, 2-CBI was found to reduce the value of charge transfer resistance (Rct) of an iron electrode that was previously covered with corrosion products. The shape of the impedance plots at 45°C was similar to those recorded at 25°C. However, Rct was always higher in the presence of 2-CBI, especially at shorter immersion times.

Corrosion of iron in aqueous solutions containing a chemical cleaning agent

The use of chelant agents as a cleaning chemicals to remove iron-based deposits is gaining interest. In this study the effect of tannic acid on the corrosion of iron in neutral solutions was studied using polarization curves, polarization resistance and AC impedance techniques at different conditions which include pH, concentration and immersion time. In neutral solutions tannic acid was found to form a protective layer as a result from the reaction between tannic acid and iron ions. The possibility of using some corrosion inhibitors was also studied. The results indicate that thiosemicarbazide with tannic acid improved the protective layer to an extent which depends on the additive concentration, pH and immersion time.

Corrosion inhibition of pure iron in neutral solutions by electrochemical techniques

Steady-state current-voltage curves for various disk rotation rates were combined with transient measurements (frequency analysis of the electrochemical and electrohydrodynamical impedance) in order to investigate the corrosion inhibition by an organic surfactant of pure iron in an aerated 0.5 M NaCl solution. In the cathodic range, physical adsorption of the compound with the interfacial potential was observed leading to the thickening or strengthening of the film. Thus, for short times of polarization, due to the adsorption relaxation, it was necessary to compensate the ohmic drop in the circuit to obtain the electrohydrodynamical (EHD) curves. The inhibitor acts by forming a porous layer covering the surface. From the analysis of the EHD diagrams the thickness and the porosity of the film were estimated. Nevertheless, a non-classical behaviour in the HF range of the EHD diagrams was observed and interpreted by a mechanical action of the fluctuating flow on the film. At the corrosion potential, the electrochemical impedance diagrams were essentially representative of the charge transfer process. Diffusion across the inhibitor film is very slow and requires extremely low modulation frequencies (below 1 mHz).

Interactions of different nonylphenolepolyethyleneglycoles (NPG) with iron electrodes

Nonylphenolepolyethyleneglycoles (NPG) are characterized by means of electrochemical methods. We made electrochemical impedance spectroscopy and current density-potential measurements at superpure iron electrodes in KNO3 solution with and without addition of NPG. In order to acquire some knowledge about the electrical potential-distance profile at the electrode surface of iron, we made Zeta potential measurements at dispersed α-Fe2O3 particles. Adsorption phenomena of NPG at electrode surfaces free of any oxide layer were studied by a.c. polarography (tensammetry) at the dropping mercury electrode. It is shown that NPG can inhibit the corrosion reaction of superpure iron in neutral solutions as combined anodic/cathodic inhibitors, but increase the cathodic process in weak acid solutions.

Analysis of the Photoelectrochemical Response of the Passive Film on Iron in Neutral Solutions

Photoelectrochemical techniques have become increasingly popular for in situ measurements related to corrosion studies and have provided a new insight into the electronic structure of passive films. Photoelectrochemical studies of the passive film formed on iron in neutral solutions are presented. The electronic properties of the film are interpreted on the basis of photocurrent measurements performed as a function of incident photon energy and electrode potential. Results indicate that the passive film on iron exhibits electronic properties similar to those of amorphous semiconductors.

ChemInform Abstract: The Mechanism of Oxygen Reduction on Iron in Neutral Solutions.

AbstractThe O2 reduction has been investigated in a borate buffer on bare iron and on passive iron.

The Mechanism of Oxygen Reduction on Iron in Neutral Solutions

The pathways and rate‐determining steps of oxygen reduction on iron in neutral pH range have been investigated. The various mechanistic criteria are obtained as a function of the nature of the electrode surface: bare iron and passive iron. The oxygen reduction on bare iron proceeds through 4e− pathways with little hydrogen peroxide as an intermediate and formation of superoxide radical in the rds. On passive iron, oxygen reduction proceeds through a 2e− pathway with the formation of hydrogen peroxide as a reaction product. An rds involving chemisorption of oxygen is suggested.

On Area Ratio of Anode to Cathode for Iron in Neutral Solution

Abstract We have succeeded in making a corrosion cell which separates the anodes from the cathodes for iron in a neutral solution. In the corrosion cell, two test pieces are faced, or put back to back, and immersed in the condition of electrical short circuit. The corrosion behavior was measured by the amount of galvanic current with a zero impedance ammeter and by weight loss. After the test, it was found that the corrosion cell of horizontally opposed electrodes could almost perfectly separate the anodes from the cathodes in the differential aeration cell formed. The galvanic current density of the anode (that is, the anodic dissolution rate) is proportional to the area ratio of anode to cathode; while the galvanic current density flowing in the cathode is not related to the area ratio and approaches the limiting current density for oxygen reduction. It is concluded that this corrosion cell can be useful for corrosion mechanism studies.

中性水溶液中の鉄表面不働態皮膜に対する生成条件およびアニオンの影響

中性水溶液中の鉄表面不働態皮膜に対する生成条件およびアニオンの影響

Corrosion fatigue behaviour of nitrogen‐implanted steel in water

AbstractThe corrosion fatigue behaviour of nitrogen implanted iron in neutral solutions has been investigated utilizing the oscillating cantilever beam method, by means of electrochemical (Ecorr vs. time plots, Rp measurements) and S. E. M. techniques.The calculated corrosion rate under stagnant conditions is lowered for the implanted iron at all nitrogen doses with respect to untreated iron. The surface oxide layers achieve enhanced protecting capacity.Consequently under a cyclic load of 25.4 kg mm−2, at a frequency of 16.6 Hz, cracks nucleation is delayed. The time to breaking of implanted specimens is considerably lower in our experimental conditions compared to untreated iron. The increase in the crack growth rate is consistent with the detrimental action of structural damage following implantation. The fracture morphology is also discussed.

ChemInform Abstract: INHIBITION OF THE CREVICE CORROSION OF IRON IN CHLORIDE SOLUTIONS BY CHROMATE

AbstractDie Spaltenkorrosion des Eisens in neutralen Lösungen wird durch Cl(‐)‐Ionen begünstigt und durch CrO4(2‐)‐Ionen gehemmt.

Inhibition of the Crevice Corrosion of Iron in Chloride Solutions by Chromate

The crevice corrosion of iron in neutral solutions is promoted by chloride ions and inhibited by chromate. For any given concentration of chloride in the range investigated , the crevice corrosion of iron can be inhibited by using a sufficient amount of chromate, with the concentration of chromate required decreasing with the concentration of chloride. A linear relationship is observed between the logarithm of the chloride ion activity and the logarithm of the minimum activity of chromate ion required for protection against crevice corrosion. This relationship is explained on the basis of competitive adsorption between aggressive (Cl−) and inhibitive ions within the crevice, with each ion adsorbing according to a Temkin isotherm. The steady‐state electrode potential of corroding iron within crevices is −620 to −660 mV vs. , independent of bulk solution composition and in reasonable agreement with the thermodynamic value calculated for an iron crevice or pit.

Effect of cathodic pretreatment on the passivation of iron in neutral solution

Pure iron specimens anodically oxidized at +600 mV ( vs sce) for one minute were partially reduced with a cathodic current of 10 μA/cm 2 and then reoxidized at the same potential for one hour. The experiment was performed in a boric acid/borate buffer solution at pH = 8.43 at room temperature. Variation in the thickness of the oxide film during the experiment is discussed for an inner Fe 3O 4 and outer γ-Fe 2O 3 layers, with emphasis on the effect of cathodic treatment. In the discussion, the amounts of charges for anodic and cathodic processes and the amount of dissolved Fe 2+ ions during the cathodic reduction are utilized.

Auger analysis of the anodic oxide film on iron in neutral solution

The composition depth-profile of anodic oxide films on iron at various potentials in a boric acid-sodium borate solution of pH 8.4 was measured by the sequential use of Auger electron spectroscopy (AES) and sputter-etching. It was found that the anodic oxide film consisted mainly of oxygen and iron with minor impurities such as boron, sulphur and carbon. The composition ratio of boron or sulphur to oxygen exhibited a maximum value at a certain depth in the outer layer of the film and the maximum value of ( B O ) increased with increasing potential up to 500 mV (SCE). The film formation mechanism is discussed from the observed dependence of boron content in the film.

Film Growth and Dissolution of Iron Ions at passive iron in neutral solutions containing chloride

AbstractThe passivating oxide layer on iron grows by transfer of oxygen ions from the solution into the oxide. As expected theoretically, the dissolution rate of iron ions increases with the growth rate of the layer. In neutral solution the current efficiency for oxide growth is larger than in acid solutions. By addition of chloride to the solution the current efficiency is further enhanced, because chloride catalyzes the transfer of oxygen ions more strongly than the transfer of iron ions. Chloride in the solution does not change the ionic conductivity of the oxide to a measurable extent. During galvanostatic polarization in solutions containing chloride, fluctuations of the potential and of the dissolution rate of Fe(II) are observed. The frequency of the fluctuations increases with current density and chloride concentration.

中性溶液における鉄不働態皮膜組成の電位依存性

中性溶液における鉄不働態皮膜組成の電位依存性

The mechanism of the passivation of iron in neutral solutions: An ellipsometric and coulometric investigation

Ellipsometric and electrochemical transient techniques have been used to investigate the pre- and post-passive region on iron in neutral solutions. In particular, a new ellipsometric transient technique allows the examination of the dissolution and film formation on iron, even though this is undergoing roughening by etching. Stationary states of the metal surface were measured by classical ellipsometry. Measurement of transient states depend on the variation of light intensity, when the initial offset angle of analyser and polarizer are respectively at an angle of 25, 0 and 90°. Potentiostatic and galvanostatic coulometry and capacitance measurements were applied. Oxide-free surfaces with visible unidirectional scratches gave different values of Δ and ψ if the position of the sample was changed with respect to the oncoming light; apparent Δ and ψ were dependent also on the degree of polishing. If the metal was held at potentials during which it dissolved in the active region for more than ca 7 min and i > 10 μA/cm 2, Δ and ψ changed with time and the original values were not re-attained on reduction; the double-layer capacitance was increased by 2–3 times by such treatment. A sufficient degree of polishing gave Δ and ψ for oxide-free iron in solution, which showed refractive index and adsorption coefficient the same as those determined by others in vacuum. The corresponding metal was taken as an oxide-free optical reference state. Coulometry showed 1–2 monolayers of a ferrous oxide at the peak of the current/potential curve. Far from this peak on the positive side, the galvanostatic transients during reduction are in two sections which correspond to a charge of 1 : 2 in the charge reduced. At less positive post-peak regions coulometry allowed evaluation of the ratio Fe 2+ : Fe 3+ in the film. Δ/potential and ψ/potential relations showed three regions; pre-peak, peak to 0 mV(she) and 0–900 mV(she). Δ/potential and ψ/potential relations measured at short (1 s) and long (300 s) times are consistent. Δ/time measurements down to 10 −2 show changes of Δ from the beginning of anodic polarization. Ellipsometric measurements are affected by roughness except at an asymptotic degree of polishing. Metal dissolution may also effect roughening to an extent which completes ellipsometrically with effects due to oxide growth. A transformation of a ferrous to a ferric oxide begins at the i/V peak and is complete at + 500 mV to the peak. Such transformations are controlled by potential, and not by field. The film before the peak is a ferrous oxide phase, probably Fe(OH) 2. Its growth kinetics indicate it is three dimensional, and formed by nucleation of adsorbed OH −. The ferric film is γ-Fe 2O 3. Film thickness l, refractive index n, and absorption coefficient, k, can be indicated within certain limits as functions of potential from ellipsometry. Application of coulometric thickness measurements to allow solution of the ellipsometric equations shows a growth of ferrous oxide to the peak, a region during which the oxide is transformed to a ferric oxide and then linear growth with potential to 40 Å. In the pre-peak region, iron dissolves from oxide-free sites to solution. The current peak corresponds, essentially, to full coverage of the surface with Fe(OH) 2. The fall of current after the peak could arise from the complete coverage. It is accompanied by the beginning of conversion to Fe 2O 3. In the passive region Fe 2O 3 growth continues.

The anodic oxide film on iron in neutral solution

The composition of the anodic passive oxide film on iron in neutral solution has been investigated by cathodic reduction, chemical analysis and ellipsometry. The cathodic reduction using a borate solution of pH 6·35 containing arsenic trioxide as inhibitor estimates iron in the film to be all iron (III), indicating that no magnetite layer is present. Oxygen in the film is estimated from the ellipsometric thickness to be in excess of the stoichiometric ferric oxide, suggesting the presence of bound water. The average composition is represented as Fe 2O 3.0·4H 2O, in which hydrogen may be replaced partly with iron-ion vacancy. The anodic oxide film is composed of an inner anhydrous ferric oxide layer, which thickens with the potential and an outer layer of hydrous ferric oxide whose thickness depends on the condition of passivation and environment. The anodic oxide film formed in the oxygen-potential region has also been measured by cathodic reduction, and it is found that the film retains nearly constant thickness above a critical potential where transpassive dissolution begins to occur.