3.1. Effect of anodization voltage and duration on AAO film thickness
Figure 2 shows the influence of anodization voltage on the AAO film thickness (4 wt% oxalic acid, 20°C). When the anodization duration is the same (4 h, 6 h or 10 h), the AAO film thickness increases approximately linearly as the voltage increases from 20 V to 60 V. A longer anodization time produces a greater film thickness growth rate. The film thickness growth rate is 1.32 µm/V for 4 h anodization, 1.74 µm/V for 6 h anodization, and 2.23 µm/V for 10 h anodization. Note that the ratio of the film thickness growth rate under different anodization duration is not equal to the ratio of the anodization duration, indicating that the duration effect on the film thickness is not a simple linear relationship.
The influence of anodization duration on the AAO film thickness is shown in Fig. 3 (4 wt% oxalic acid, 20°C). When the anodization voltage is the same (20 V, 40 V or 60 V), as the anodization duration is prolonged from 2 to 16 h, the film thickness first increases approximately linearly and then the rising speed gradually slows down. The initial film thickness growth rate is calculated by using the data within 6 h, and it is 2.90 µm/h for 20 V, 6.12 µm/h for 40 V, and 10.71 µm/h for 60 V. That is, a higher voltage results in a thicker film thickness and a higher initial film thickness growth rate. The initial linear growth is similar to the results reported in relevant literature [15, 21]. For instance, Zaraska et al. [15] gave an ideal linear film thickness growth with a slope of 9.46 µm/h (0.3 M oxalic acid, 45 V, 20°C). On the other hand, it is also found that higher voltage causes the film thickness to deviate more rapidly from the linear relationship with time. More specifically, when the voltage is 20 V, a favorable linear relationship can be maintained well until 10 h. However, it is 8 h at 40 V, and 6 h at 60 V. In addition, on the AAO sample anodized at 60 V and for 16 h, it is found that the ordered porous morphology is destroyed, and flocculated deposits appear on its surface (not shown here).
Figure 4 shows an example of current variation during anodization process (40 V, 4 wt% oxalic acid, 20°C). In the initial 1 min of the constant voltage mode, the current fluctuates violently, which is associated with the formation of the barrier oxide layer [22]. Next, the anodization current reaches a peak value and then slowly decreases during the subsequent 6 h oxidation process. A similar current trend (oxalic acid, 40 V, 18°C) was given in the literature [23]. Regarding the reduced current (or current density), the seemingly simple and reasonable explanation is that the increased film thickness increases its resistance. It is generally accepted that the AAO film thickness is defined by anodization time and current density according to Faraday law. Therefore, the gradual decrease in current during the anodization process seems to be an appropriate explanation for the depressed film thickness growth rate shown in Fig. 3. Shang et al. [23] researched the preparation of uniform pore structure in oxalic acid solution through voltage compensation mode. They proposed that in the traditional AAO preparation method, as the anodization duration prolonged, the pore length gradually increased, and the ion concentration (directly involved in oxidation) in the front of the pore would reduce gradually, resulting in a decrease in current. Belwalkar et al. [21] also reported similar research conclusions.
3.2. Effect of electrolyte temperature and electrolyte concentration on volume expansion factor
This section examines the influence of electrolyte temperature and concentration on the AAO film thickness and volume expansion factor. Figure 5 shows the changes of AAO film thickness, volume expansion factor and current density with electrolyte temperature (4 wt% oxalic acid, 40 V, 6 h). The current density in Fig. 5 is calculated based on the average current in the initial 2 ~ 4 min of the anodization process (as shown in Fig. 4).
When the electrolyte temperature increases from 5 to 30°C, the current density increases almost exponentially. The change trend of film thickness is roughly similar to the current density, although it becomes more linear when temperature exceeds 20°C. This synchronization indicates that the increase in film thickness may be related to the exponential increase in current density caused by the increase in electrolyte temperature. On the other hand, despite the continuous increase in film thickness, the volume expansion factor first increases from 1.21 at 5°C to 1.28 at 10°C, and then gradually drops to 1.13 at 30°C. Kao et al. [19] investigated the influence of phosphoric acid electrolyte temperature (0 ~ 7°C, 10 wt%, 160 V) on the volume expansion factor of AAO film. Similar to the result shown in Fig. 5, as the temperature of phosphoric acid increased, the current density and film thickness increased almost synchronously, but the volume expansion factor first rose gradually (0 ~ 5°C) and then dropped rapidly (5 ~ 7°C).
According to the results in Fig. 5 and the relevant literature [17, 19, 21], the increase in volume expansion factor within 5 to 10°C should be attributed to the increase in current density caused by the enhanced electrolyte temperature. It was reported that the increased electrolyte temperature accelerated the ionization of aluminum at the oxide/aluminum interface [19]. Simultaneously, as the electrolyte temperature increased, the concentration of hydroxide and oxygen ions from the hydrolysis of the conjugate base of the acids would also increase at the oxide/electrolyte interface, which intensified the diffusion and drift across the oxide layer and formation of Al2O3 with Al3+ at the oxide/aluminum interface [19]. The promoted aluminum ionization and the increased O2−/OH− ion concentration led to the increase in current. Belwalkar et al. [21] proposed that the increased current provided greater impetus for larger volume expansion, and thereby pushed more oxide up the walls, resulting in higher thickness. Similarly, Vrublevsky et al. [17] reported that the volume expansion factor depended on the electric field strength in the barrier layer, and the increase in electric field strength in the barrier layer resulted in the increase of volume expansion factor.
It is generally accepted that the AAO film thickness is dictated by dynamic equilibrium of oxidation and chemical dissolution [13, 21]. More specifically, the growth mechanism of the AAO film depends on the equilibrium between the oxide formation at the metal/oxide interface and the oxide dissolution at the electrolyte/oxide interface [13]. The reactions involved in the electrochemical anodization process are shown as follows: 1) 2Al + 3H2O → Al2O3 + 6H+ + 6e (oxidation at anode); 2) Al2O3 + 6H+ → 2Al3++3H2O (dissolution at anode); 3) 6H+ + 6e → 3H2 (at cathode). Belwalkar et al. [21] proposed that the dynamic equilibrium of the oxide formation (highly dependent on the acid concentration and availability of oxygen ions) and dissolution (relatively constant due to its field-assistant nature) caused a characteristic limiting thickness [21]. Accordingly, it is possible that the oxide dissolution is responsible for the decreased volume expansion factor within 10°C to 30°C shown in Fig. 5.
Herein, an approximate corrosion experiment was performed to investigate the influence of the AAO film dissolution caused by the acidic electrolyte on the volume expansion factor. After the secondary anodization, the voltage was adjusted to 0 V, and the resulting AAO sample was continuously immersed in the original electrolyte for the same time as the secondary oxidation (electrolyte conditions remain unchanged). The corrosion effect was investigated by using the film thickness variation before and after corrosion treatment.
As shown in Fig. 5, immersing the prepared AAO sample in acidic electrolyte results in a film thickness loss. Below 20°C, the film thickness loss is not remarkable. When the AAO sample is subjected to the corrosion treatment above 20°C, the film thickness loss almost increases exponentially with the electrolyte temperature. It is acceptable that at temperatures below 20°C weak corrosion causes the film thickness and current density to increase synchronously and exponentially. At temperatures higher than 20°C, however, strong corrosion breaks the synchronization between film thickness growth and current density, and the film thickness growth rate deviates from the current increase rate under the combined effect of current density and corrosion. In other words, the strengthened alumina dissolution above 20°C is believed to be the main reason for the decreased volume expansion factor in the range of 10 ~ 30℃.
The changes of film thickness (after anodization or after corrosion treatment), current density and volume expansion factor with electrolyte concentration are shown in Fig. 6. Increasing the electrolyte concentration from 2–8% causes the current density and the film thickness increase slowly and synchronously, but the increase amplitude is much weaker than the case of adjusting the electrolyte temperature. The increased electrolyte concentration also slightly promotes the corrosion treatment effect after anodization. The enhanced ion concentration caused by the increased electrolyte concentration is considered to be responsible for the approximately linear increase of current density. Simultaneously, since the film thickness produced by anodic oxidation or the film thickness loss caused by corrosion treatment increases approximately linearly with the electrolyte concentration, the volume expansion factor also shows a linear change trend. Kao et al. [19] investigated the influence of phosphoric acid concentration on the volume expansion factor, and provided a first rising and then dropping trend. Different conclusions should be associated with different anodization conditions. It is well known that the electrolyte type greatly affects the AAO film morphology. Due to the strong corrosiveness of phosphoric acid, phosphoric acid electrolyte is frequently used to prepare AAO film with large pore diameter (typically 300 nm), while the typical pore diameter in oxalic acid is about 50 nm. Therefore, different corrosion properties are thought to lead to different variation trends of volume expansion factor.
It should be noted that the aforementioned corrosion test is only an approximate method, because it cannot fully reflect the dissolution effect during the anodization process. However, this approximate test undoubtedly shows that the corrosion phenomenon during anodization is non-ignorable. The following research shows that the oxide dissolution during anodization is also greatly affected by the electric field.
3.3. Effect of anodization voltage and duration on volume expansion factor
The influence of voltage on the volume expansion factor is shown in Fig. 7. It is obvious that the volume expansion factor gradually increases with voltage. There is an ideal linear relationship between voltage and volume expansion factor, especially for 4 h anodization and 6 h anodization. However, the linear relationship slightly worse when the anodization time reaches 10 h. The least square method is used to determine the curve slope. With the prolongation of anodization duration, the curve slope gradually decreases, 0.014 V− 1 for 2 h anodization, 0.013 V− 1 for 6 h anodization, and 0.011 V− 1 for 10 h anodization. A linear relationship between voltage and volume expansion factor has also been confirmed in the relevant literature [17, 24]. For instance, Vrublevsky et al. [17] reported a linear relationship between voltage and volume expansion factor, i.e., k = 1.092 + 0.007U (k: volume expansion factor; U: voltage V; 20 ~ 50 V, 4 wt% oxalic acid, 20°C). The difference between the linear formula in Fig. 7 and that reported in the literature [17] may be caused by different oxidation conditions. Although the voltage (20 ~ 50 V), electrolyte type (oxalic acid), concentration (4 wt%), and temperature (20°C) are the same as this work, the sample size (0.75 cm × 0.75 cm) and film thickness (1.8 µm) used in the literature [17] are significantly different from those used in this work due to the different research purposes.
In Fig. 7, it is also found that the volume expansion factor is affected by anodization duration. However, to the best of our knowledge, the relationship between volume expansion factor and anodization duration is rarely mentioned in the relevant literature. Next, we discuss how the volume expansion factor changes with anodization duration under different voltages (Fig. 8). As shown in Fig. 8, under three voltages, with the prolongation of anodization duration, the volume expansion factor roughly shows a change trend of first rising and then falling (the latter half of the 40 V curve has a relatively small slope). Moreover, as the voltage increases, the time point at which the maximum volume expansion factor appears gradually shifts to the left. That is, the higher the voltage is, the earlier the peak value appears. In addition, as voltage increases, the absolute value of the curve slope gradually decreases in the rising stage of volume expansion factor, while increases in the falling stage.
As mentioned above, the film thickness growth is determined by the competition between electric field-controlled oxidation and corrosion-controlled dissolution, as shown in Figs. 5 and 6. However, when other influencing factors are not considered, at the same acid concentration and temperature, the oxide corrosion rate in acidic solutions should be approximately constant and not change with time. The experiment shown in Fig. 9 also confirmed this conjecture. In Fig. 9, the AAO material (40 V, 6 h, 4 wt% oxalic acid, 20°C) is subjected to the corrosion treatment (0 V, 4 wt% oxalic acid, 20°C) to investigate the alumina corrosion effect with time. It can be seen from Fig. 9 that the thickness loss (or quality loss) has a linear relationship with the corrosion duration. In other words, the corrosion rate is approximately constant when voltage = 0 V. The contradiction between the constant corrosion rate and the first rising and then falling trend of volume expansion factor can be explained by field-assisted nature of AAO dissolution [21].
The actual anode surface temperature during anodization process was measured to investigate the field-assisted nature of AAO dissolution. Four Al substrates were prepared, and the sample size was 3 cm × 4.5 cm for S1, 3 cm × 9 cm for S2, 3 cm × 4.5 cm for S3, and 3 cm × 9 cm for S4, respectively. A thermocouple was fixed close to the Al plate by using waterproof tape. The other side of Al plate was exposed to the electrolyte. The oxidizable area of Al plate was adjusted by changing the coverage area of waterproof tape, as shown in Fig. 10. Another thermocouple was placed in the middle between the Al plate and the cathode to measure the electrolyte temperature. Samples S1 ~ S4 were anodized in 4 wt% oxalic acid and at 20°C, and the adopted voltage was 40 V for S1, 40 V for S2, 60 V for S3, and 60 V for S4. The actual anode surface temperature during anodization process was recorded online, as shown in Fig. 11. During the anodization process, the electrolyte temperature (E1 ~ E4) is well maintained at about 20°C, and no appreciable change is observed. However, the anode surface temperature is much higher than the electrolyte temperature, and a higher voltage produces a higher anode surface temperature. For example, the surface temperature of S2 anodized at 40 V is about 40°C, while the temperature of S4 anodized at 60 V is as high as 77°C. It is considered that the high temperature of the local oxide is caused by the Joule-heating effect of oxidation reaction [19, 20]. Although the electrolyte temperature remains almost constant during the anodizing process, the Joule-heating effect significantly increases the anode surface temperature, which thereby greatly promotes the AAO film dissolution (i.e., Joule heat-enhanced dissolution).
During the anodization process, as voltage, electrolyte temperature or electrolyte concentration increase, current (or current density) increases, and more Al is ionized into Al3+ ions, namely field-assisted ionization and thermally-enhanced ionization [19]. Simultaneously, the concentration of hydroxide and oxygen ions from the hydrolysis of the conjugate base of the acids also increases at the oxide/electrolyte interface [17]. As a result, more alumina is produced and leads to a larger volume expansion factor. However, when an excessively high voltage or electrolyte temperature is used, the Joule heat of oxidation will greatly increase the actual local oxide temperature by tens of degrees and accelerate the dissolution process, resulting in the decreased volume expansion factor (or its rising-rate slows down).
The effect of anodization duration on the expansion volume factor is discussed below. After the anodization for a long time, a large film thickness of tens of microns (long pore length) can be obtained. The diffusion distance of tens of microns and the small pore diameter of tens of nanometers limit the diffusion of ions into the pores (more precisely, the pore bottom). The ion concentration in the pores directly involved in the oxidation reaction decreases gradually, which inhibits the film growth rate. The electric field strength in the pore may also change due to the increase in resistance. In this case, in comparison with the effect of oxidation reaction on AAO film growth, the effect of Joule heat-enhanced dissolution becomes more prominent. The longer the oxidation time, the deeper the pores and the more obvious the limiting effect on film growth. Therefore, in the latter half of the test in Fig. 8, the volume expansion factor decreases with the prolongation of anodization duration. A higher voltage produces a stronger Joule heating effect, which makes the maximum value of volume expansion factor appear earlier. Moreover, as mentioned in Fig. 8, as voltage increases, the absolute value of the curve slope gradually increases in the falling stage of volume expansion factor. This phenomenon is attributed to the fact that the high voltage intensifies the effect of Joule heat-enhanced dissolution. This is also believed to be a reasonable explanation for the lower slope of the hollow-lower-triangle curve (in Fig. 7, anodized for 10 h) than those anodized for the shorter time. In addition, this also accounts for the non-linear relationship between film thickness and anodization duration, as shown in Fig. 2.
We do not have enough evidence to explain the increased volume expansion factor shown in the first half of the test in Fig. 8. It is speculated that this may be related to the diffusion of Al3+ ions in pores. Part of Al3+ ions produced by aluminum ionization reacts with O2− to form alumina. Another part of Al3+ diffuses to the oxide/electrolyte interface, and a large number of Al3+ ions appear near the interface. These Al3+ ions react with OH− ions to form negatively-charged aluminum hydrate and deposit on the anode. It is supposed that this deposition also contributes to the volume expansion factor to some extent. When the film thickness is relatively small, some Al3+ ions may directly diffuse into the electrolyte bulk, instead of reacting with OH− ions and depositing on the anode. Appropriate pore length may limit the Al3+ ion diffusion into the electrolyte bulk through the confinement effect. It is speculated that this is one of the reasons why the volume expansion factor increases with the anodization duration prolongation in the first half of the test in Fig. 8. Further research is in progress.
In addition, in Fig. 11, the comparison between S1 and S2 (or S3 and S4) shows that as the sample size increases, the Joule heating effect becomes more obvious, because the larger sample size shows a higher surface temperature. For example, under the same voltage (60 V), the surface temperature of S3 (3 cm × 4.5 cm) is about 53°C, while that of S4 (3 cm × 9 cm) is about 77°C. In other words, the larger the sample size, the higher the voltage, and the more significant the Joule-heating effect. Note that S1 ~ S4 samples used in Fig. 11 were anodized under a single-sided anodization model. In the case of double-sided model, the Joule-heating effect should be more obvious. It is understandable that under the same conditions, the growth rate of the large-sized AAO film is higher than that of the small-sized AAO film in the first half of the preparation process because the Joule-heating effect accelerates the film growth. However, in the subsequent stage, since Joule heat promotes both the growth rate and the dissolution rate, the growth rate of the large-sized AAO film is slower than that of the small-sized AAO film. Eventually, an equilibration is achieved between growth and dissolution. In this process, the Joule heat also acts as a catalyst to speed up the process and shorten the equilibration time, especially when high voltage is applied. According to the above discussion, how to control heat transfer is considered to be the key to manufacture a thick and large-sized AAO film. Even if the conventional anodization conditions (electrolyte type, concentration, temperature, voltage/current density, duration) are the same, sample size, electrolyte capacity, circulating cooling flow rate and other heat transfer-related conditions will greatly affect the AAO film growth, which are often ignored in the relevant literature. Relevant literature has investigated the effect of aluminum purity, which is also considered to be associated with the Joule-heating effect. Generally, because a small amount of impurities in the aluminum substrate (generally less than 1%) significantly changes the Joule heat of anodization, different pore morphologies [20] or film thickness growth rates [15] are obtained on aluminum substrates with different purity.
Based on the research of this work, for preparing a thick and large-sized AAO film, the anodization voltage and duration are considered to be more effective and easily-controlled parameters than electrolyte temperature or concentration. A voltage of about 30 ~ 50 V and a duration of 2 ~ 10 h are preferred preparation parameters, because the film thickness has a linear relationship with the voltage or duration. Under these conditions, a maximum thickness of about 100 µm can be obtained, and the ordered pore structure is well retained, which provides a favorable foundation for further modifying the AAO material as a catalyst support.