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Article

Corrosion Behavior of Pure Ti under a Solid NaCl Deposit in a Wet Oxygen Flow at 600 °C

1
Institute of Metal Research, Chinese Academy of Sciences, Wencui Road 62, Shenyang 110016, China
2
Key Laboratory for Anisotropy and Texture of Materials (MoE), School of Materials Science and Engineering, Northeastern University, Shenyang 110819, China
*
Authors to whom correspondence should be addressed.
Metals 2016, 6(4), 72; https://doi.org/10.3390/met6040072
Submission received: 27 January 2016 / Revised: 12 March 2016 / Accepted: 17 March 2016 / Published: 24 March 2016

Abstract

:
The corrosion behavior of pure Ti under a solid NaCl deposit in a wet O2 flow at 600 °C has been studied. The results showed that the corrosion rate was greatly accelerated by solid NaCl, which destroyed the compact and protective TiO2 scale to yield non-protective N4Ti5O12 and other products. Detailed scanning electron microscopy (SEM) equipped with an energy dispersive spectrometer (EDX), and X-ray diffraction (XRD) analysis showed that, during the corrosion process, the metal (Ti) diffused outward rapidly and reacted with the wet O2 to form a thick and porous corrosion products scale. The electrochemical reaction was also observed during the whole corrosion process at 600 °C, which further accelerated the corrosion rate. A possible mechanism has been proposed for pure Ti covered with a solid NaCl deposit in wet O2 at 600 °C, based on the experimental results.

Graphical Abstract

1. Introduction

It is widely known that compressor blades suffer more serious corrosion when serving in a marine condition than in an inland condition. This is mainly because, in the marine environment, the working compressor blades are surrounded by moist air, which contains abundant salt (especially NaCl) and water vapor. Since compressor blades generally serve at 300–600 °C (intermediate temperature), NaCl is in solid state and can form a solid deposit layer on the blades surface. As a result, compressor blades would suffer serious corrosion in the simultaneous presence of a solid NaCl deposit layer and wet air.
Under this combined effect of NaCl and wet O2 at 500–700 °C, the corrosion behavior of several alloys, including Fe-Cr alloys [1], 1Cr11NiW2MoV steel [2], 304 stainless steel [3], and K38G alloy [4], has been extensively studied. To better understand the corrosion mechanism of these alloys, further studies have been conducted to study the corrosion behavior of pure Fe [5,6,7] and pure Cr [5,8,9], which are the major alloy elements of the blade materials. The results demonstrate that the corrosion rate of pure Fe and pure Cr is sensitive to the presence of a solid NaCl deposit layer because the solid NaCl deposit could react with their oxide at 500–700 °C. This reaction destroys the protective oxide scale formed on the metal surface, and the gathered Cl2 or HCl reacts with substrate metal cyclically, resulting in a fast corrosion. Additionally, electrochemical reactions have been observed during the corrosion process and were involved in the whole corrosion process [5,6,7,9]. The interaction of chemical reactions with electrochemical reactions accelerates the corrosion rate significantly.
Titanium alloys are considered appropriate materials for compressor blades because of their superior strength/weight ratio, good creep resistance, and excellent mechanical properties [10,11]. Even some titanium alloys, e.g., Ti-1100 [12], IMI 834 [13], and Ti60 [14], have been used in the compressor at 600 °C (which is the highest serving temperature for compressor blades in application). The corrosion behavior of titanium alloys under the combined effect of a solid NaCl deposit layer and water vapor at 500–700 °C has been already studied [14,15,16]. Compared with the good corrosion resistance at room temperature [17,18,19,20], titanium alloys, on the other hand, suffer a serious corrosion at 600 °C [14,15,16]. Additionally, the element Ti, the main alloy element for titanium alloys, is sensitive with solid NaCl at 600 °C, and its oxide (TiO2) forms the main corrosion products. Thus, in order to reach a clear understanding on the corrosion mechanism of titanium alloys in the serving condition of compressor blades and on the corrosion behavior of element Ti in the whole corrosion process of titanium alloys, it is necessary to study the corrosion behavior of pure Ti under the combined effect of a solid NaCl deposit layer and wet O2 at 600 °C in details.
In this paper, the corrosion behavior of pure Ti underneath a solid NaCl deposit layer in wet O2 flow has been investigated at 600 °C using scanning electron microscopy (SEM) equipped with an energy dispersive spectrometer (EDS), X-ray diffraction (XRD), and in situ electrochemical measurement. Possible mechanisms have been discussed based on the experimental results.

2. Materials and Methods

The material used in this study was pure Ti, and the samples were cut into pieces of 10 mm × 15 mm × 2 mm. All the samples were mechanically ground to 800 grit (including the edges rounded off) with SiC paper, cleaned in alcohol, and dried in the air. By repeatedly brushing and drying a NaCl-saturated aqueous solution onto the preheated samples [1,2,3,4,8,14], a solid NaCl layer was deposited on the sample surface. In this work, the amount of deposited NaCl was about 4 ± 0.2 mg/cm2.
The corrosion tests were carried out in a thermo-balance [1,2,3,4,8,14]. Thermo-gravimetric analysis (TGA) was applied to record the continuous mass gain during the corrosion experiment. The corrosion atmosphere (wet O2) was obtained by bubbling pure O2 into distilled water in a glass bubbler (in this study, the flow rate of pure O2 was about 140 mL/min when the inner diameter of the tube was about 3.2 cm). The volume fraction of water vapor was controlled by adjusting the temperature of distilled water in the glass bubbler. In this study, the temperature of distilled water was about 60 °C, producing a wet O2 flow with 19.6 vol % water vapor. To prevent the water vapor from condensing inside the thermo-balance, a counter flow of pure N2 was passed through the thermo-balance. After the furnace reached the desired temperature (600 °C), and the flows of wet O2 and pure N2 stabilized, the sample was quickly lowered into the constant temperature zone of the furnace tube.
In this work, the corrosion experiments were conducted under the following corrosion environments: solid NaCl deposit layer in a wet O2 flow at 600 °C (NWO600); solid NaCl deposit layer in a dry O2 flow at 600 °C (NO600); wet O2 flow at 600 °C (WO600); and dry O2 flow at 600 °C (O600). The specific environmental parameters have been presented in Table 1.
After corrosion, the surface and the cross-sectional morphologies of the samples were collected by SEM/EDX. The chemical composition of corrosion products was investigated by XRD.
A special three-electrode system was built for the in situ electrochemical measurements in this particular environment (shown in Figure 1) [6]. To decrease the resistance of the solution and achieve a uniform electric field, the reference electrodes consisted of four platinum wires with a diameter of 0.5 mm, and the counter electrode was a circular strip of platinum foil about 0.2 mm wide. All potential values in this paper were reported versus this platinum reference electrode. The working electrode, pure Ti, was a rod with a length of 10 mm and a diameter of 5 mm. The three electrodes were in quartz tubes, which acted as insulators. All the gaps were sealed by a high temperature inorganic glue [6,7,9]. To decrease the interference of the furnace electric current, the connection wire was covered with a metal shielding layer. After deposited a solid NaCl layer, the three-electrode system was directly put into the furnace at the desired temperature for in situ electrochemical measurements.
The PAR2273 Electrochemical Measurement System manufactured by EG & G was used for all the electrochemical measurements, which also has the ability to compensate the resistance between reference electrode and working electrode. In galvanic corrosion measurement, the ratio of anodic area to cathodic area is 1:2. All the electrochemical measurements were repeated at least three times.

3. Results

3.1. Gravimetry

The mass gain curves of pure Ti under different conditions are shown in Figure 2. The results indicate that, in the absence of the solid NaCl deposit (O600 and WO600), the mass gain of pure Ti is very low during the testing time (20 h). Particularly, the mass gain in WO600 is a little larger than in O600; thus, the water vapor slightly accelerates the corrosion rate of pure Ti without NaCl. In contrast, the mass gain in NO600 and NWO600 increases by a factor of approximate 20, compared with the exposure in O600 and WO600. This demonstrates that pure Ti suffers much more serious corrosion in the presence of solid NaCl at 600 °C. In other words, pure Ti is sensitive to the solid NaCl deposit. Furthermore, the mass gain in NWO600 is a little larger than in NO600, which indicates that water vapor further accelerates the corrosion rate of pure Ti in the presence of a solid NaCl deposit.

3.2. Morphologies and Composition of the Corrosion Products

Figure 3 shows the surface and the cross-sectional morphologies of pure Ti after the samples were exposed in O600 for 20 h. It indicates that a compact and even oxidation scale is formed on the sample surface after 20 h exposure in pure O2 at 600 °C, and its thickness is about 1 μm. Figure 4 shows the surface and the cross-sectional morphologies of pure Ti after the samples were exposed in WO600 for 20 h. These morphologies (Figure 4a–c) present that the oxidation scale is compact and even. As shown in Figure 4c, its thickness is about 1.5 μm, which is a little thicker than that of O600 (Figure 3c). This means that pure Ti suffers more serious corrosion in the wet O2 flow, which agrees with the results of the mass gain in Figure 2. Furthermore, when pure Ti is exposed in the wet O2, the oxidation scale is layered and can be divided into two layers: the inner layer and the outer layer. The inner layer is compact, and its thickness is about 0.5 μm. The outer layer is porous (containing hole marked in Figure 4c), and its thickness is about 1 μm.
The surface and the cross-sectional morphologies of pure Ti after 20 h exposure in NO600 are shown in Figure 5. It can be observed that the corrosion product scale contains the compact structure products and the grid structure products. The compact structure products (marked in Figure 5a,b) are very complete and uniform. The grid structure products (marked in Figure 5a,b) contain lots of through holes (filled with Ni plating, as shown in Figure 5b) penetrating the corrosion scale. These through holes are the fast diffusion path for corrosion medium. Underneath the corrosion scale, a loose layer, containing some holes (close pores), is formed within the substrate due to the diffusion outward of Ti. The thickness of the corrosion products scale is about 60 μm, while that of the loose layer is about 12 μm.
Figure 6 shows the surface and the cross-sectional morphologies of pure Ti after 20 h exposure in NWO600. The results indicate that the corrosion products scale also contains the compact structure products and the grid structure products. Compared with that one formed in NO600 (Figure 5), the compact structure products are relatively looser and lumpier in NWO600, and the grid structure products contain more through holes. Additionally, a loose layer is formed under the corrosion scale, and its thickness is about 15 μm. Compared with exposure in NO600, this loose layer forming in NWO600 is thicker and contains more and larger holes and cracks. Hence, there are more Ti diffusing outward, and the corrosion is more serious in the simultaneous presence of a solid NaCl deposit and water vapor, which is consistent with the results of mass gain in Figure 2.
Figure 7 shows the XRD patterns of the corrosion products. Figure 7a shows that only TiO2 is formed on the surface of pure Ti after 20 h exposure in O600 and WO600 (pure Ti identified in Figure 7a is the substrate). The XRD patterns in Figure 7b show that, when pure Ti is exposed in the presence of a solid NaCl deposit (NO600 and NWO600), a mixture of corrosion products (containing Na4Ti5O12 and TiO2) forms on the sample surface with some residual NaCl. In Figure 7b, it also appears that the intensity of diffraction peaks of Na4Ti5O12 is larger in NWO600 than in NO600. This means that the water vapor enhances the formation of Na4Ti5O12 in the presence of a solid NaCl deposit.

3.3. Electrochemical Corrosion

Figure 8 shows the galvanic corrosion current (Ig) as a function of time for the Pt–Pt couple under NWO600 and the Ti–Pt couple under NWO600. In Figure 8a, Ig of the Pt–Pt couple under NWO600 increases quickly to 7 × 10−7 A/cm2 in the early stage due to the increase of test temperature and then decreases form the top to −2 × 10−8 A/cm2 with time varying from 0 to 5 h. Ig of the Ti–Pt couple under NWO600 (Figure 8b) is also divided into a fast increase stage and then a decrease stage. Ig of the Ti–Pt couple under NWO600 is about three orders of magnitude larger than that of the Pt–Pt couple under NWO600, with the maximum value about 1.7 × 10−4 A/cm2.
The variation of open circuit potential (EOCP) with corrosion time for pure Ti under NWO600 is presented in Figure 9 and show that EOCP increases quickly to −0.35 V vs. Pt in the early stage due to the increase of test temperature, and then it always declines with corrosion time to −0.6 V vs. Pt after 20 h exposure.

4. Discussion

4.1. Electrochemical Reaction in the Corrosion Process of Pure Ti under a Solid NaCl Deposit

When pure Cr and pure Fe were exposed in a marine condition at 600 °C, the electrochemical reactions, observed by Liu et al. [5] and Tang et al. [6,7,9], were involved in the whole corrosion process; thus, the entire corrosion included electrochemical corrosion and chemical corrosion. The electrochemical corrosion was weak but accelerated the corrosion rate greatly by interacting synergistically with the chemical corrosion [6,7,9]. For pure Ti, the measured Ig of the Ti–Pt electrodes under NWO600, which is 1.7 × 10−4 A/cm2 as shown in Figure 8c, is significantly larger than that of the Pt–Pt electrodes, which is near to zero as shown in Figure 8a. Since no electrochemical reaction occurs on the Pt–Pt electrodes under NWO600 [5,6], its Ig is believed to be the background current density of the whole electrochemical system. Additionally, the value of the measured Ig for the Ti–Pt electrodes is close to the normal electrochemical reaction in the solution. Therefore, it is believed that electrochemical reactions should occur with pure Ti, and electrochemical corrosion is considered to be involved in the corrosion process of pure Ti under NWO600, which is similar with the results of pure Cr [9] and pure Fe [6,7] exposed in the same condition. This means that the entire corrosion of pure Ti under NWO600 includes the electrochemical corrosion reaction and the chemical oxidation reaction.
The percentage of the electrochemical corrosion to the total corrosion (ratio of electrochemical corrosion rate to total corrosion rate) was calculated, because it provides useful insight into the corrosion behavior of pure Ti in the presence of a solid NaCl deposit at 600 °C. The total corrosion rate (consumption of Ti over the entire corrosion) can be calculated by mass gain measurements. The ratio of atom Ti to atom O is assured for the oxidation product, since the oxidation product is approximately TiO2 (as shown in Figure 7b). Additionally, the corrosion product is mainly composed of oxygen, involved in the corrosion process, and the metal, consumed by corrosion. Thus, the total corrosion rate of the consumed metal (Ti) can be determined from the slope of the mass gain results (Figure 2) according to the ratio of atoms. The electrochemical corrosion rates (consumption of Ti through the electrochemical reaction) can be calculated from the corrosion current density (Icorr) which is obtained by fitting the potentiodynamic polarization curves (Figure 10) in the cathodic active polarization zones. The calculation method is described in detail in [9] and the obtained results are presented in Table 2. When pure Ti is exposed in NWO600 respectively for 1 h, the percentage of the electrochemical corrosion to the total corrosion is about 2.43%, while it is about 4.88% after 20 h of exposure.
We could conclude from this that the electrochemical corrosion occurs during the whole corrosion process in NWO600, but its ratio to total corrosion is very low (less than 5%).

4.2. Corrosion Behavior of Pure Ti under a Solid Deposit

The corrosion is slight when pure Ti is exposed in dry O2 without NaCl at 600 °C (Figure 2) due to an even, continuous and compact TiO2 scale formed on the surface (Figure 3). This scale protects the substrate from corrosion.
Ti + O2 = TiO2
When pure Ti is exposed in the presence of water vapor without NaCl, the oxidation rate is amplified slightly (Figure 2), and a layered and thicker oxide scale is formed on the sample surface (Figure 4c). Additionally, the results of XRD (Figure 7a) indicate that the corrosion product is only TiO2. Thus, we can conclude that the composition and the crystal structure of the oxide scale are even, and the difference between the two layers is just their compactness. At high temperature, H2O tends to dissociate at the defects on TiO2/(110) planes into free H atoms and OH groups [21,22,23]. The generated hydrogen atoms are more prone to diffuse into TiO2 through the crystal channels in the c-axis direction, along which the diffusion rate is at least one order of magnitude larger than that in the direction perpendicular to c-axis [21,22]. This dissolution of hydrogen in TiO2 can increase the concentration of crystal defects by forming hydrogen defects, thereby increasing the diffusion outward of Ti ions [23]. This fast diffusion in the scale result in a larger corrosion rate and the hole formed in the oxide scale (marked in Figure 4c), which leads to a thicker and more porous layer (Figure 4c).
When pure Ti is covered with a solid NaCl deposit layer, the corrosion rate is seriously accelerated (Figure 2) since the corrosion product scale is non-protective and the protective TiO2 scale cannot be formed in the presence of a solid NaCl deposit (Figure 5a,b). The protective TiO2 scale cannot form due to the occurrence of a series of chemical reactions, which are the main actors during the whole corrosion, and lead to an active corrosion. Firstly, the TiO2 scale reacts with NaCl and O2 [14], which destroys the protective scale:
5TiO2 + 4NaCl + O2 = Na4Ti5O12 + 2Cl2
Additionally, this destructive reaction can occur as following:
6TiO2 + 4NaCl = Na4Ti5O12 + TiCl4
TiCl4 + O2 = TiO2 + 2Cl2
The generated Cl2 in Reactions (2) or (4) diffuses inward quickly through the through holes in the porous corrosion products scale (Figure 5b) and reacts with the substrate (Ti) [2,8,14].
Cl2 + Ti = TiCl2
2Cl2 + Ti = TiCl4
Due to high vapor pressure and high activity at 600 °C, TiCl2 and TiCl4 diffuse outward quickly and react with O2 immediately [14] through the following reaction and Reaction (4) respectively.
TiCl2 + O2 = TiO2 + Cl2
The standard Gibbs free energy changes (ΔG°) of these reactions at 600 °C are presented in Table 3. ΔG° of these reactions are negative; thus, the reactions are thermodynamically spontaneous. The generated Cl2 in Reactions (4) and (7) can diffuse inward and react with substrate again. Thus, Cl2 reacts with the substrate cyclically, resulting in the diffusion outward of the metal (Ti) forming the hole and the cracks in the loose layer as shown in Figure 5b and the fast corrosion. Additionally, TiO2 is mainly formed by the chemical sedimentation of the Reactions (4) and (7), and the gaseous species (Cl2, TiCl2, and TiCl4) are produced in the corrosion process; therefore, the produced TiO2 is porous and non-protective.
In the presence of water vapor, the corrosion rate of pure Ti under a solid NaCl deposit is a little larger than that without H2O (Figure 2). The corrosion mechanism is similar to that in NO600 and discussed as following.
5TiO2 + 4NaCl + 2H2O = Na4Ti5O12 + 4HCl
TiCl4 + 2H2O = TiO2 +4HCl
2HCl + Ti = TiCl2 + H2
4HCl + Ti = TiCl4 + 2H2
2TiCl2 + O2 + 2H2O = 2TiO2 +4HCl
2H2 + O2 = 2H2O
TiCl4 in the Reaction (9) is produced through Reaction (3). These reactions are also thermodynamically spontaneous due to the negative ΔG°, as presented in Table 3. Thus, NaCl destroys the protective scale through Reactions (3) and (8), and HCl reacts with the substrate cyclically. Due to the higher activity of HCl than that of Cl2, the rates of Reactions (10) and (11) are larger than Reactions (5) and (6). Additionally, the concentration of crystal defects is greater by forming hydrogen defects due to the dissolution of H2O into TiO2 as previously discussed. Thus, more Ti is consumed and then diffused outward, resulting in larger corrosion rate (Figure 2) and looser corrosion products scale (Figure 6). This higher consumption of Ti also results in a thicker loose layer with more holes and cracks underneath the corrosion product scale as shown in Figure 6b.
TiCl4, TiCl2, Cl2, HCl, and H2 act repeatedly in the reaction and have a very short lifetime. Thus, it is difficult to exactly identify the chemical species.
On the other hand, the electrochemical corrosion occurs during the whole corrosion process when pure Ti is exposed in NWO600, which has been discussed. For pure Ti, the anodic reaction is simple.
Ti = Ti4+ + 4e
This anodic reaction could enhance the consumption of metal (Ti) in the corrosion process; thus, the electrochemical reaction maybe further aggravate the corrosion in NWO600.

5. Conclusions

The corrosion rate of pure Ti under a solid NaCl deposit in a wet O2 flow at 600 °C was greatly amplified by the solid NaCl. The corrosion product scale is very porous and thick in the presence of solid NaCl. We believe that solid NaCl reacts with Ti oxides to form Na4Ti5O12, which decreases the protective ability of the corrosion product scale, thereby aggravating the corrosion process. Meanwhile, the electrochemical reaction, which is slight during the whole corrosion process, promotes metal transfer into metal cations and aggravates the corrosion further.

Acknowledgments

This investigation was supported by the National Key Basic Research and Development Plan of China under the Contract No. 2014CB643303, the National Natural Science Foundation of China under the Contract No. 51371181, the National Natural Science Foundation of China under the Contract No. 51531007 and the International S&T Cooperation Program of China (ISTCP) (No. 2014DFR50560).

Author Contributions

The tests were carried out by Lei Fan, characterization was performed by Lei Fan and Li Liu, the experimental scheme was framed by Fuhui Wang. The manuscript was composed by Lei Fan and revised by Li Liu, Min Cao, Zhongfen Yu and Minghui Chen.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Schematic diagram of three-electrode cell: (a) the top view and (b) the cross-section view.
Figure 1. Schematic diagram of three-electrode cell: (a) the top view and (b) the cross-section view.
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Figure 2. Corrosion kinetics curves of pure Ti under different corrosion environments at 600 °C: (I) dry O2 (black line), (II) H2O + O2 (green line), (III) NaCl + O2 (red line), (IV) NaCl+ H2O + O2 (purple line).
Figure 2. Corrosion kinetics curves of pure Ti under different corrosion environments at 600 °C: (I) dry O2 (black line), (II) H2O + O2 (green line), (III) NaCl + O2 (red line), (IV) NaCl+ H2O + O2 (purple line).
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Figure 3. Surface morphologies (a); high magnification image (b) and cross-sectional morphologies (c) of pure Ti oxidized in dry O2 at 600 °C for 20 h.
Figure 3. Surface morphologies (a); high magnification image (b) and cross-sectional morphologies (c) of pure Ti oxidized in dry O2 at 600 °C for 20 h.
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Figure 4. Surface morphologies (a); high magnification image (b) and cross-sectional morphologies (c) of pure Ti oxidized in wet O2 at 600 °C for 20 h.
Figure 4. Surface morphologies (a); high magnification image (b) and cross-sectional morphologies (c) of pure Ti oxidized in wet O2 at 600 °C for 20 h.
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Figure 5. Surface morphologies (a) and cross-sectional morphologies (b) of pure Ti under a solid NaCl deposit layer in dry O2 at 600 °C for 20 h.
Figure 5. Surface morphologies (a) and cross-sectional morphologies (b) of pure Ti under a solid NaCl deposit layer in dry O2 at 600 °C for 20 h.
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Figure 6. Surface morphologies (a) and cross-sectional morphologies (b) of pure Ti under a solid NaCl deposit layer in wet O2 at 600 °C for 20 h.
Figure 6. Surface morphologies (a) and cross-sectional morphologies (b) of pure Ti under a solid NaCl deposit layer in wet O2 at 600 °C for 20 h.
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Figure 7. X-ray diffraction patterns of pure Ti oxidized in dry O2 and wet O2 up to 20 h at 600 °C (a) and X-ray diffraction patterns of pure Ti under a solid NaCl deposit layer in dry O2 and wet O2 at 600 °C for 20 h (b).
Figure 7. X-ray diffraction patterns of pure Ti oxidized in dry O2 and wet O2 up to 20 h at 600 °C (a) and X-ray diffraction patterns of pure Ti under a solid NaCl deposit layer in dry O2 and wet O2 at 600 °C for 20 h (b).
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Figure 8. Galvanic corrosion current of the Pt–Pt couple (a) and Ti–Pt couple (b) under a solid NaCl deposit layer in wet O2 at 600 °C.
Figure 8. Galvanic corrosion current of the Pt–Pt couple (a) and Ti–Pt couple (b) under a solid NaCl deposit layer in wet O2 at 600 °C.
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Figure 9. Open circuit potential of the Ti–Pt couple under a solid NaCl deposit layer in wet O2 at 600 °C.
Figure 9. Open circuit potential of the Ti–Pt couple under a solid NaCl deposit layer in wet O2 at 600 °C.
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Figure 10. Potentiodynamic polarization plot of the pure Ti under a solid NaCl deposit layer in wet O2 at 600 °C for 1 h (a) and 20 h (b).
Figure 10. Potentiodynamic polarization plot of the pure Ti under a solid NaCl deposit layer in wet O2 at 600 °C for 1 h (a) and 20 h (b).
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Table 1. Experimental parameters.
Table 1. Experimental parameters.
EnvironmentMass of NaCl (mg/cm2)Amount of Water Vapor (vol %)Flow Rate of O2 (mL/min)Temperature (°C)
NWO6004.019.6140600
NO6004.00140600
WO600019.6140600
O60000140600
Table 2. Electrochemical corrosion potential (Ecorr), electrochemical corrosion rates (Icorr), and percentage of electrochemical corrosion to total corrosion of pure Ti under a NaCl deposit in wet O2 at 600 °C for 1 and 20 h.
Table 2. Electrochemical corrosion potential (Ecorr), electrochemical corrosion rates (Icorr), and percentage of electrochemical corrosion to total corrosion of pure Ti under a NaCl deposit in wet O2 at 600 °C for 1 and 20 h.
ConditionCorrosion Time (h)Ecorr (V vs. Pt)Icorr (A/cm2)Percentage of Electrochemical Corrosion to Total Corrosion
NWO6001−0.3885.04 × 10−52.43%
NWO60020−0.4363.02 × 10−54.88%
Table 3. Standard Gibbs free energy changes of reactions at 600 °C.
Table 3. Standard Gibbs free energy changes of reactions at 600 °C.
ReactionΔG° kJ/mol
Ti + O2 → TiO2−785
4NaCl + 5TiO2 + O2 → Na4Ti5O12 + 2Cl2−194
4NaCl + 6TiO2 → Na4Ti5O12 + TiCl4−65
TiCl4 + O2 → TiO2 + 2Cl2−129
Ti + Cl2 → TiCl2−374
Ti + 2Cl2 → TiCl4−656
TiCl2 + O2 → TiO2 + Cl2−411
4NaCl + 5TiO2 + 2H2O → Na4Ti5O12 + 4HCl−195
TiCl4 + 2H2O → TiO2 + 4HCl−130
Ti + 2HCl → TiCl2 + H2−174
Ti + 4HCl → TiCl4 + 2H2−256
2TiCl2 + 2H2O + O2 → 2TiO2 + 4HCl−905
2H2 + O2 → 2H2O−399

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MDPI and ACS Style

Fan, L.; Liu, L.; Cao, M.; Yu, Z.; Li, Y.; Chen, M.; Wang, F. Corrosion Behavior of Pure Ti under a Solid NaCl Deposit in a Wet Oxygen Flow at 600 °C. Metals 2016, 6, 72. https://doi.org/10.3390/met6040072

AMA Style

Fan L, Liu L, Cao M, Yu Z, Li Y, Chen M, Wang F. Corrosion Behavior of Pure Ti under a Solid NaCl Deposit in a Wet Oxygen Flow at 600 °C. Metals. 2016; 6(4):72. https://doi.org/10.3390/met6040072

Chicago/Turabian Style

Fan, Lei, Li Liu, Min Cao, Zhongfen Yu, Ying Li, Minghui Chen, and Fuhui Wang. 2016. "Corrosion Behavior of Pure Ti under a Solid NaCl Deposit in a Wet Oxygen Flow at 600 °C" Metals 6, no. 4: 72. https://doi.org/10.3390/met6040072

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