Figure 1.
Schematic diagram of the microarc oxidation setup: 1-power supply, 2-sample, 3-condensed water, 4-thermometer, 5-stirrer.
In this study, we sought to prepare sangorache encapsulate (Amaranthus quitensis L.) by spray- and freeze-drying, using three different concentrations (3, 5 and 7%) of the encapsulating agent, maltodextrin. To atomize the powder, we used a Buchi mini spray-dryer B-290 with three inlet temperatures (140, 160 and 180 ℃) and a laboratory freeze dryer with a −0.8 bar pressure for 4 days. During atomization, the powders presented lower moisture content and water activity with the addition of maltodextrin; however, there were no significant changes in the moisture of the freeze-dried powders. Colorimetric analysis revealed that the luminosity (L) and chroma (C) values changed as maltodextrin concentration increased. The structures of particles were examined by scanning electron microscopy (SEM) SEM, and very different morphological characteristics resulted from the two drying methods. Also, apparent density, hygroscopy and dissolution testing revealed significant differences between the powders. Sangorache antioxidant compounds were preserved to a greater extent by applying low concentrations of the encapsulating agent and by the freeze-drying technique. The natural colorant from sangorache inflorescences could serve as an additive to improve food color in the industry.
Citation: María Quelal, Elena Villacrés, Karla Vizuete, Alexis Debut. Physicochemical characterization of sangorache natural colorant extracts (Amaranthus quitensis L.) prepared via spray- and freeze-drying[J]. AIMS Agriculture and Food, 2023, 8(2): 343-358. doi: 10.3934/agrfood.2023019
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In this study, we sought to prepare sangorache encapsulate (Amaranthus quitensis L.) by spray- and freeze-drying, using three different concentrations (3, 5 and 7%) of the encapsulating agent, maltodextrin. To atomize the powder, we used a Buchi mini spray-dryer B-290 with three inlet temperatures (140, 160 and 180 ℃) and a laboratory freeze dryer with a −0.8 bar pressure for 4 days. During atomization, the powders presented lower moisture content and water activity with the addition of maltodextrin; however, there were no significant changes in the moisture of the freeze-dried powders. Colorimetric analysis revealed that the luminosity (L) and chroma (C) values changed as maltodextrin concentration increased. The structures of particles were examined by scanning electron microscopy (SEM) SEM, and very different morphological characteristics resulted from the two drying methods. Also, apparent density, hygroscopy and dissolution testing revealed significant differences between the powders. Sangorache antioxidant compounds were preserved to a greater extent by applying low concentrations of the encapsulating agent and by the freeze-drying technique. The natural colorant from sangorache inflorescences could serve as an additive to improve food color in the industry.
Titanium and its alloys are utilized in aerospace, marine, and biomedical fields due to their low density, good electrical and thermal conductivity, and ease of mechanical processing [1,2]. While they generally offer satisfactory wear resistance, they can undergo accelerated wear under extreme operating conditions [3,4,5,6]. Wear resistance is particularly crucial for titanium-based medical implants and prostheses, which must endure persistent mechanical stresses. Moreover, although biocompatible, these materials sometimes show suboptimal osseointegration, necessitating surface modifications to enhance bone tissue interaction [2,7]. Surface treatments such as plasma chemical deposition, thermal oxidation, anodizing, and chemical vapor deposition create thin films on titanium surfaces. However, these methods fall short in producing coatings with the desired porosity and thickness control that are essential for improved corrosion resistance and durability against intense wear [8,9,10,11].
Microarc oxidation (MAO), also referred to as plasma electrolytic oxidation (PEO), is an efficacious surface treatment technique that enhances the hardness and wear resistance of titanium and its alloys through the formation of ceramic coatings [12,13]. MAO significantly improves the wear resistance of coatings, rendering titanium alloys more suitable for biomedical applications such as implants and prostheses. This enhancement is achieved by forming oxide coatings on the titanium surface, which not only improve the tribological properties but also offer augmented protection against corrosion. MAO generates a thin yet robust oxide layer and can yield structurally complex coatings, which play a critical role in enhancing biocompatibility and promoting osseointegration [14,15,16,17,18,19].
To further enhance the properties of titanium alloys, selecting the appropriate electrolytes is crucial. A variety of acidic, saline, and alkaline electrolytes can be employed for MAO treatments on titanium and titanium alloys, such as silicates, potassium fluoride, sodium hydroxide, sodium tetraborate, and sodium phosphate, among others. For instance, sodium hydrogen phosphate (Na2HPO4), as utilized in reference [20], was shown to produce coatings that not only reduce corrosion rates but also exhibit biological activity. Moreover, the inclusion of phosphoric acid and powders of hydroxyapatite and wollastonite in the electrolyte solution has been found to increase the osteogenic potential of fibroblast-like cells adhering to a Ti40Nb alloy, attributable to alkaline phosphatase activity [21]. An electrolyte solution containing calcium carbonate (CaCO3) has been demonstrated to yield coatings on magnesium substrates with favorable anticorrosive and self-healing properties [22]. Research in [23] revealed that adding sodium orthophosphate (Na3PO4) to the baseline electrolyte was sufficient to augment the chemical and mechanical resistance of the MAO coatings without affecting their surface roughness and thickness. The most commonly employed electrolyte for MAO is a mixed phosphate-alkaline solution, specifically KOH-Na3PO4. Studies [24,25] have explored how the electrolyte composition influences the intensity and size of microdischarges, as well as the volume of gas evolution. In the KOH-Na3PO4 mixture, potassium hydroxide (KOH) serves as an activator that facilitates enrichment, leading to the formation of a reinforcing layer on the oxidized surface. The enhanced corrosion resistance of samples processed with equal proportions of silicate and KOH is likely due to increased coating thickness, less porous surface morphology, and higher resistance of the internal barrier layer [26]. Coatings containing aluminates display a volcanic morphology characterized by a mix of nodular particles and craters across the surface. Phosphate-based coatings exhibit a sintered structure replete with craters, alongside an uneven distribution of micropores and microcracks, which are linked to porosity. Silicate-containing coatings are distinguished by their highly porous framework, constituted by a network of micropores and oxide granules [27]. Phosphate-based electrolytes are considered the most promising, given their superior efficiency in forming coatings and the lowest breakdown voltage [28]. While most substances within the coating are not directly involved in plasma reactions, chemical, electrochemical, and thermally induced reactions are predominant in coating formation [29]. The type of electrolyte significantly influences the Ca/P ratio in MAO coatings because different electrolytes affect the incorporation and distribution of calcium and phosphorus within the coatings. Study [30] examines a PEO process in which various metal oxides are incorporated into the coating, affecting not only corrosion resistance but also, potentially, the chemistry, including the Ca/P ratio. Double introduction of molybdenum oxide (MoO2) and silicon oxide (SiO2) affects the protective properties of coatings, which can indirectly affect the Ca/P ratio due to changes in the electrolyte composition and interaction dynamics during the PEO process [31]. Although this study primarily focuses on mechanical properties, it shows how changes in electrolyte components (e.g., titanium oxide (TiO2) nanoparticles) can alter surface characteristics and underlying chemical structures, possibly affecting the Ca/P ratio [32]. Combining the data from these studies, it becomes clear that the type of electrolyte and the additives used (such as TiO2, MoO2, and SiO2 nanoparticles) significantly influence the elemental composition and distribution within PEO coatings. This effect extends to the Ca/P ratio, which can vary depending on how these elements are incorporated into coatings during the PEO process. Changes in the Ca/P ratio are critical as they can affect the mechanical properties and biocompatibility of coatings, which are especially important in biomedical applications [30,31,32,33].
Previous research has demonstrated that MAO treatment enhances the performance of various alloy coatings. This suggests that the electrolyte composition is a critical factor in improving the properties of these coatings. Despite these advances, there remains a notable lack of detailed studies on the mechanical and tribological properties of MAO coatings applied to VT1-0 titanium substrates. Furthermore, comprehensive investigations into how the electrolyte composition correlates with coating properties—knowledge crucial for practical applications—are sparse [34,35,36]. In the present study, phosphates and calcium carbonates were employed as the primary components in the MAO electrolytes for modifying VT1-0 alloys. This research is focused on assessing the impact of the resulting coatings on the microstructure and corrosion resistance when applied to VT1-0 alloys via MAO. Given the direct influence of coating properties on the performance of the materials in service, the insights gained from this study are of substantial practical significance [37,38,39,40]. The aim of this article is to explore the influence of different electrolyte compositions on the mechanical, tribological, and corrosion properties of titanium coatings fabricated through the MAO technique.
The coating using the MAO method was applied with a pulsed power supply, specifically a KP-HI-F-40A 600V rectifier. The MAO apparatus comprises a programmable switching power supply, an electrochemical bath with cooling capabilities, and a set of electrodes (Figure 1). Overall, the operational setup for the MAO process includes: power equipment—namely, the power supply; baths for surface preparation, treatment, and rinsing; and auxiliary equipment such as cooling systems.
The parameters of the MAO process for this work are presented in Table 1. According to the literature, 300 V was chosen as the optimal voltage parameter for MAO [41,42]. When performing MAO, the current is in the range of 0.50–0.70 A. Samples of titanium alloy VT1-0 with dimensions 2 × 2 × 2 cm, pre-polished and prepared for the experiment, were used as the substrate material. The current density was calculated using the Eq 1:
| (1) |
where I is the current in amperes, and A is the surface area in square meters through which the current passes.
| Frequency, Hz | Voltage, V | Current density, A/cm2 | Time, sec | Pulse duration, mks |
| 100 | 300 | 0.13–0.17 | 600 | 100 |
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In accordance with the object of study, three different electrolyte compositions were selected, as shown in Table 2. The samples were immersed in an aqueous solution (500 mL of distilled water) of the electrolyte and microarc oxidation was carried out.
| Regimes | Electrolyte |
| No. 1 | Na2HPO4 (5 g), hydroxyapatite (HA) (2 g), KOH (2 g) |
| No. 2 | Н3PO4 (15%), HA (2 g), СаСО3 (5 g) |
| No. 3 | Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) |
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The surface morphology of the coatings was examined using a fourth generation TESCAN VEGA scanning electron microscope with a thermionic tungsten cathode. To calculate porosity, the ImageJ software package, designed for image processing and analysis, was used. The phase composition of the coatings was studied by X-ray diffraction (XRD) analysis using an X-pertPRO X-ray diffractometer using CuKα radiation (1.5406 Å) in standard Bragg–Brentano geometry. The following parameters were used for X-ray diffraction measurements: X-ray tube voltage—40 kV, X-ray tube current—30 mA, scan angle range—20–60°, scan step size—0.0200, and signal acquisition time—1 s. The roughness of the coatings was measured using a HY2300 Anytester profilometer. The sample is installed on the profilometer table. It is important to properly align the sample so that the surface is parallel to the direction of the probe movement. The profilometer probe, which is usually a microscopically thin needle, contacts the surface of the sample and moves along a specified area. In this case, the probe records the vertical movement necessary to maintain contact with the surface, which allows the generation of a roughness profile. Hardness determination was carried out using the FISCHERSCOPE HM2000 S measuring system in accordance with the requirements of the DIN EN ISO 14577-1 standard. A load of 300 mN was chosen for testing. Primary processing of the test results was carried out using the software of the WIN-HCU device. A tetrahedral Vickers diamond pyramid with a plane angle of 136° was used as an indenter. Tribological tests were carried out under the following conditions: load up to 3 N, speed—2.5 cm/s, radius—2 mm, ball radius (silicon nitride (Si3N4) counterbody) —3 mm. Corrosion tests were carried out by the potentiodynamic method using a single-channel potentiostat-galvanostat model CS300M in a 3.5% sodium chloride (NaCl) solution at a temperature of ±25 ℃. To obtain the area under study, materials such as tape and varnish were used; a protective coating of varnish was used to isolate the area of the sample not being studied. To enable comparison of the results when conducting potentiodynamic studies, it is extremely important that the analyzed areas on the tested samples are identical. This is necessary so that the values obtained during testing of the samples under the same conditions are comparable. In one glass cell, there is a reference electrode (R) with a known constant potential—a silver chloride electrode filled with a NaCl solution with a pH value of 6, and in the second cell, there is an auxiliary electrode (C)—a platinum electrode and a working electrode (W)—the test titanium samples with and without coatings with a surface area of 0.25 cm2. The cells are connected by a salt bridge containing sodium chloride and both sides are covered with filter paper, designed to prevent the mixing of solutions in the cells. This is necessary to ensure accurate potential measurements as mixing may affect the results. Before installing the test sample into the circuit, it is prepared by cleaning and removing greasy contaminants using ethyl alcohol. The CS Studio6 program allows you to determine the values of the potential, current density, corrosion rate, as well as Tafel slopes (ba, bc). The graphs are presented in logarithmic form (the current density scale is presented in logarithmic form). In addition, it provides the ability to visually monitor the construction of curves of value changes on a computer.
The surface morphology of the coatings is shown in Figure 2. During the investigation of the surface morphology of the coatings, a noticeable difference in structure and porosity was observed between the used electrolyte compositions. For further examination of the surface and to achieve additional functional properties of titanium, MAO was performed in various electrolytes. As a result of these processes, as presented in Figure 2 (a, b, and c), noticeable changes in surface morphology and the formation of oxide layers with unique properties were observed.
The resulting coating using electrolyte No. 1 showed a more pronounced porous structure. This porosity may be due to a combination of electrolyte components, including KOH, which contributes to the formation of pores in the oxide layer. The process involving KOH can lead to the formation of a porous structure in oxide coatings [43,44]. Gases released as a result of reactions on the surface create micropores in the resulting oxide films. This effect was further enhanced by the choice of certain electrolyte formulations, such as Na2HPO4 [45], which contain components that promote the formation of gases. The coating obtained using electrolyte No. 2 has a less pronounced porous structure. The presence of H3PO₄ in the electrolyte contributes to the formation of a denser and more compact oxide layer [46]. It is also worth noting that with this electrolyte composition, the oxidation process was actively proceeding, resulting in pronounced macro-irregularities with holes. Unlike coatings with electrolytes No. 1 and No. 2, the coating using electrolyte No. 3 does not exhibit noticeable porosity. This can be explained by the balance between Na3PO4, HA, and CaCO3, which ensures the formation of a denser oxide layer. The absence of pores indicates a more structurally compact nature for this coating. Large sparks lead to the formation of large and small micropores, while smaller sparks form smaller micropores and, as a result, form a more homogeneous structure [47].
The average size of micropores and the percentage of porosity are shown in Table 3. Porosity was measured using ImageJ, a versatile and powerful image analysis software widely used in the scientific community and particularly useful for analyzing the porosity of materials using microscopic images. This process provides a quantitative measurement of porosity, which is important in materials science for applications such as assessing the structural integrity and characteristics of materials, and for other purposes [48,49,50]. According to Figure 2, the pores are evenly distributed and have the same size. Electrolyte No. 2 (Figure 2e) is characterized by visible large pores shaped as large spheres, which were formed as a result of an active oxidation process due to the concentration of orthophosphoric acid in the electrolyte.
| Electrolyte | Average pore size, µm | Percentage of porosity, % |
| No. 1: Na2HPO4 (5 g), HA (2 g), KOH (2 g) | 2.21 | 9.5 |
| No. 2: Н3PO4 (15%), HA (2 g), СаСО3 (5 g) | 4.78 | 4.9 |
| No. 3: Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) | 0.003 | 0.2 |
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An important point is the elemental analysis (Figure 3), which revealed the presence of elements such as calcium, phosphorus, oxygen, and sodium, which make up the electrolyte and the substrate material, titanium. The absence of pronounced phases of these elements can be explained by their low mass content, as well as the amorphousness of the thin coatings obtained during MAO [51,52,53,54,55].
The mechanism of formation of MAO coatings on Ti substrates was revealed using energy dispersive X-ray spectroscopy (EDS) analysis. The MAO coating contained Ti, O, Ca, P, and Na. Na was obtained from the electrolyte. The Ti content was 56.92 wt.%, showing that the electrolyte affects the color and properties of the coating. In our study, two forms of sodium phosphate were used across different electrolytes: Na2HPO4, a dibasic sodium phosphate in No. 1, and Na3PO4, a tribasic sodium phosphate in No. 3. Tribasic sodium phosphate generally exhibits higher solubility and a greater rate of dissociation in aqueous solutions compared to its dibasic counterpart [56]. This leads to a significantly enhanced availability of sodium ions during electrolysis with No. 3, thereby increasing their likelihood of being incorporated into the coating. Conversely, the presence of KOH in No. 1 increases the pH, which may induce precipitation of some sodium ions as less soluble compounds, reducing the availability of free sodium ions for incorporation into the coating. In No. 3, CaCO3 reacts
with phosphate ions to form calcium phosphate, thereby maintaining a higher concentration of free sodium ions in the solution, which facilitates their deposition onto the substrate.
The X-ray image obtained from the surface of the coatings and the initial titanium is shown in Figure 4.
Analysis of the diffraction patterns of coatings formed by electrolytes No. 1, No. 2, and No. 3 confirms the presence of rutile and anatase phases of titanium dioxide (TiO2). These phases are formed as a result of the interaction of the titanium substrate with oxygen coming from electrolyte solutions during the MAO process. The detection of titanium crystal phases also highlights the efficiency of the processing and the formation of stable oxide layers.
The roughness value is shown in Table 4. The presence of irregularities is due to sandblasting before sample preparation. Consequently, no significant changes in surface roughness were detected. Electrolyte No. 2 has a higher roughness due to the formation of micro-irregularities on the surface.
| Regimes | Roughness (Ra), µm |
| Initial | 3.13 ± 0.5 |
| No. 1: Na2HPO4 (5 g), HA (2 g), KOH (2 g) | 3.24 ± 0.9 |
| No. 2: Н3PO4 (15%), HA (2 g), СаСО3 (5 g) | 3.96 ± 0.8 |
| No. 3: Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) | 3.03 ± 0.2 |
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Differences in the compositions of electrolytes lead to the formation of oxide coatings with different structures and properties. High values of microhardness indicate the effectiveness of the MAO method in improving the mechanical properties of the surface of the material. The microhardness results are presented in Table 5.
| Regimes | HV0.1 | H, MPа | E, MPа |
| Initial | 151.3 ± 1.0 | 15.4 ± 1.5 | 120.5 ± 1.5 |
| No. 1: Na2HPO4 (5 g), HA (2 g), KOH (2 g) | 327.8 ± 2.8 | 33.4 ± 1.2 | 153 ± 2.2 |
| No. 2: Н3PO4 (15%), HA (2 g), СаСО3 (5 g) | 267.1 ± 3.4 | 27.2 ± 2.1 | 115.2 ± 2.8 |
| No. 3: Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) | 291 ± 1.3 | 26.7 ± 1.1 | 132 ± 1.9 |
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A significant increase in the microhardness of MAO coatings compared to the initial titanium indicates the formation of a solid oxide layer due to the formation of rutile and anatase phases. Rutile has a high hardness, and its preparation in coatings improves their mechanical properties, such as hardness and scratch resistance. The microhardness of electrolyte No. 1 is two times greater than the initial sample.
The coefficient of friction of the coatings obtained in the MAO process can vary depending on several factors, including the composition of the coating, surface roughness, environmental conditions, and the analog material with which the coating interacts. The coefficient of friction is an indicator of the slip resistance between two contacting surfaces and depends on both the internal properties of the coating and external factors [57,58]. Rutile, as a rule, has a higher hardness compared to anatase, which reduces wear and, thereby, the coefficient of friction in tribological systems. The measurement of the coefficient of friction for the first electrolyte was 0.109 µ, for the second was 0.133 µ, and for the third was 0.532 µ, compared to the initial uncoated titanium, which was 0.773 µ. The images show signs of wear resulting from the tribological testing of the surfaces of the original and coated samples. The initial sample (Figure 5a) shows significant wear, characterized by a long, deep scratch. This indicates significant material removal and path deformation, indicating aggressive wear conditions. The smoother surface with little wear on No. 1 (Figure 5b) indicates less wear and a more durable finish than the original. No. 2 (Figure 5c) shows signs of wear in the form of a blurred, spotted pattern. This suggests more distributed wear due to abrasive particles. No. 3 (Figure 5d) shows a wear pattern with a jagged edge. This morphology may indicate delamination or cracking of the material. It is worth noting that the surface of the third coating has fewer pores, which may not retain lubricant as effectively. These wear marks help evaluate the durability and resistance of surface treatments or coatings under simulated or actual operating conditions.
Figure 5 shows micrographs and surface profiles of the wear marks of the substrate before and after the MAO. It can be seen that the wear trace of the substrate of the initial titanium is wide and deep, which indicates a high degree of wear during tribological application. However, the wear mark of the MAO coating No. 1 becomes shallow and narrow. This clearly demonstrates the MAO coating's improvement in the titanium alloy's anti-wear properties and its very low coefficient of friction during slip tests. The increase in wear resistance is due to the compact microstructure and high hardness of the oxide ceramic coating.
According to the results of the corrosion test, the values were obtained (Table 6), which show increases in the corrosion resistance of the samples after the MAO. During corrosion resistance studies, polarization curves were obtained (Figure 6). Titanium and its alloys have a strong tendency to form a protective oxide layer when exposed to an electrolyte, which can alter the electrochemical behavior, especially under anodic conditions. The change in linearity of the curves may reflect differences in the stability between samples. This passive film may be very thin, but is highly protective, causing the observed current density to decrease as the potential moves away from the corrosion potential. Moreover, the observed nonlinearity may also be influenced by the microstructure of the titanium alloy itself, including variations in alloying elements, grain size, and the presence of intermetallic phases, which can influence how uniformly the passive layer forms and behaves under anodic polarization [59].
| Samples | −Ecorr, mВ | Icorr, А/сm² | rcorr, mm/a | Tafel slopes, mV | |
| ba | bc | ||||
| Initial | 218.87 | 6.0461E−06 | 0.12294 | 834.37 | −361.68 |
| No. 1 | 132.17 | 3.5191E−07 | 0.0041284 | 379.43 | −86.935 |
| No. 2 | 52.177 | 4.2888E−07 | 0.0050313 | 220.49 | −359.68 |
| No. 3 | 44.49 | 8.663E−07 | 0.010163 | 966.84 | −170.35 |
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The initial sample has the highest corrosion potential (least negative), indicating a relatively more noble behavior, but with a significant current density once it begins to corrode, suggesting that it may not be very resistant to corrosion in this environment. The curve of the initial titanium is the most negative, indicating that untreated titanium has the greatest tendency to corrosion under these test conditions. The anode slope is quite steep—834.37 mV, which indicates a strong dependence of the anode reaction on the potential. Electrolyte No. 1 is the most positive and flat of the curves, which indicates better corrosion resistance, thanks to effective MAO treatment that has changed the properties of the surface. The anode and cathode slopes are lower, indicating more stable reactions on the electrode surface. Electrolyte No. 2 has a moderate improvement in corrosion resistance compared to the initial sample, but less effective than sample No. 1. Electrolyte No. 3 has improved corrosion resistance compared to the initial titanium, but worse than samples No. 1 and No. 2, which may indicate less effective microarc oxidation treatment in terms of corrosion resistance fortitude. The interaction of Na2HPO4 and KOH leads to the formation of more stable phosphate compounds on the titanium surface, which improves the quality of the MAO coating. High concentrations of H3PO4 can lead to a more aggressive MAO process, resulting in a less uniform coating. However, the presence of HA and CaCO3 stabilizes the coating to some extent due to the formation of phosphate, which is known to have good bioactivity and corrosion resistance.
Overall, the treatment improved the corrosion resistance of the titanium samples, with sample No. 1 showing the most significant improvement. The exact nature of electrolyte compositions and their effect on surface characteristics will be important for understanding the causes of differences in electrochemical behavior. The corrosion resistance of titanium alloys is significantly influenced by the composition of the electrolyte used in the MAO process. Although all of the treated samples showed improvements over untreated titanium, differences in electrolyte components, such as phosphate sources, alkaline additives, and the presence of calcium compounds, play a critical role in determining the effectiveness of the corrosion resistance provided by MAO coatings. This expanded section provides greater insight into the corrosion behavior of titanium samples processed under various conditions, clearly relating electrolyte composition to observed electrochemical characteristics and offering a detailed explanation of the underlying mechanisms influencing the corrosion resistance of each sample. Installation using a reference electrode in one cell, a counter (platinum) and a working electrode (samples) in another, with a salt bridge connecting them, is standard for such measurements and allows for clear comparison of the samples.
The study demonstrated the significant influence of the electrolyte composition on the quality and characteristics of coatings formed on titanium substrates using microarc oxidation. It was found that the variety of electrolytic compositions directly affects the microstructure, porosity, and mechanical properties of coatings, including microhardness and corrosion resistance. Particularly noteworthy was the role of the electrolyte with the addition of KOH, which contributed to the formation of highly porous coatings with improved mechanical properties. These coatings demonstrated not only improved mechanical properties, but also increased wear resistance and corrosion resistance compared to the original titanium.
This study confirms that microarc oxidation is an effective technology for improving the performance of titanium alloys, making it promising for use in industrial and biomedical applications. The results of this work expand the understanding of the relationship between electrolyte chemistry and coating properties, which may facilitate the development of new electrolyte compositions for targeted control of coating properties.
This study also highlights the need for further detailed studies of the mechanical and tribological properties of coatings created by microarc oxidation to ensure their practical application in various operating conditions.
The authors declare that they have not used artificial intelligence (AI) tools in the creation of this article.
Main experimental work and data analysis: A.Zh. and D.B.; methodology: A.Sh. and K.O; project administration: B.R. and T.A.; writing—original draft: B.R. and A.Zh.; writing—review and editing: A.Zh. All authors have read and agreed to the published version of the manuscript.
This research has been funded by the Science Committee of the Ministry of Science and Higher Education of the Republic of Kazakhstan (Grant No. AP13068451).
The authors declare no conflict of interest.
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Figures(3) / Tables(4)
María Quelal, Elena Villacrés, Karla Vizuete, Alexis Debut. Physicochemical characterization of sangorache natural colorant extracts (Amaranthus quitensis L.) prepared via spray- and freeze-drying[J]. AIMS Agriculture and Food, 2023, 8(2): 343-358. doi: 10.3934/agrfood.2023019
| Frequency, Hz | Voltage, V | Current density, A/cm2 | Time, sec | Pulse duration, mks |
| 100 | 300 | 0.13–0.17 | 600 | 100 |
DownLoad:
CSV
| Regimes | Electrolyte |
| No. 1 | Na2HPO4 (5 g), hydroxyapatite (HA) (2 g), KOH (2 g) |
| No. 2 | Н3PO4 (15%), HA (2 g), СаСО3 (5 g) |
| No. 3 | Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) |
DownLoad:
CSV
| Electrolyte | Average pore size, µm | Percentage of porosity, % |
| No. 1: Na2HPO4 (5 g), HA (2 g), KOH (2 g) | 2.21 | 9.5 |
| No. 2: Н3PO4 (15%), HA (2 g), СаСО3 (5 g) | 4.78 | 4.9 |
| No. 3: Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) | 0.003 | 0.2 |
DownLoad:
CSV
| Regimes | Roughness (Ra), µm |
| Initial | 3.13 ± 0.5 |
| No. 1: Na2HPO4 (5 g), HA (2 g), KOH (2 g) | 3.24 ± 0.9 |
| No. 2: Н3PO4 (15%), HA (2 g), СаСО3 (5 g) | 3.96 ± 0.8 |
| No. 3: Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) | 3.03 ± 0.2 |
DownLoad:
CSV
| Regimes | HV0.1 | H, MPа | E, MPа |
| Initial | 151.3 ± 1.0 | 15.4 ± 1.5 | 120.5 ± 1.5 |
| No. 1: Na2HPO4 (5 g), HA (2 g), KOH (2 g) | 327.8 ± 2.8 | 33.4 ± 1.2 | 153 ± 2.2 |
| No. 2: Н3PO4 (15%), HA (2 g), СаСО3 (5 g) | 267.1 ± 3.4 | 27.2 ± 2.1 | 115.2 ± 2.8 |
| No. 3: Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) | 291 ± 1.3 | 26.7 ± 1.1 | 132 ± 1.9 |
DownLoad:
CSV
| Samples | −Ecorr, mВ | Icorr, А/сm² | rcorr, mm/a | Tafel slopes, mV | |
| ba | bc | ||||
| Initial | 218.87 | 6.0461E−06 | 0.12294 | 834.37 | −361.68 |
| No. 1 | 132.17 | 3.5191E−07 | 0.0041284 | 379.43 | −86.935 |
| No. 2 | 52.177 | 4.2888E−07 | 0.0050313 | 220.49 | −359.68 |
| No. 3 | 44.49 | 8.663E−07 | 0.010163 | 966.84 | −170.35 |
DownLoad:
CSV
| Frequency, Hz | Voltage, V | Current density, A/cm2 | Time, sec | Pulse duration, mks |
| 100 | 300 | 0.13–0.17 | 600 | 100 |
| Regimes | Electrolyte |
| No. 1 | Na2HPO4 (5 g), hydroxyapatite (HA) (2 g), KOH (2 g) |
| No. 2 | Н3PO4 (15%), HA (2 g), СаСО3 (5 g) |
| No. 3 | Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) |
| Electrolyte | Average pore size, µm | Percentage of porosity, % |
| No. 1: Na2HPO4 (5 g), HA (2 g), KOH (2 g) | 2.21 | 9.5 |
| No. 2: Н3PO4 (15%), HA (2 g), СаСО3 (5 g) | 4.78 | 4.9 |
| No. 3: Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) | 0.003 | 0.2 |
| Regimes | Roughness (Ra), µm |
| Initial | 3.13 ± 0.5 |
| No. 1: Na2HPO4 (5 g), HA (2 g), KOH (2 g) | 3.24 ± 0.9 |
| No. 2: Н3PO4 (15%), HA (2 g), СаСО3 (5 g) | 3.96 ± 0.8 |
| No. 3: Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) | 3.03 ± 0.2 |
| Regimes | HV0.1 | H, MPа | E, MPа |
| Initial | 151.3 ± 1.0 | 15.4 ± 1.5 | 120.5 ± 1.5 |
| No. 1: Na2HPO4 (5 g), HA (2 g), KOH (2 g) | 327.8 ± 2.8 | 33.4 ± 1.2 | 153 ± 2.2 |
| No. 2: Н3PO4 (15%), HA (2 g), СаСО3 (5 g) | 267.1 ± 3.4 | 27.2 ± 2.1 | 115.2 ± 2.8 |
| No. 3: Na3PO4 (5 g), HA (3 g), СаСО3 (5 g) | 291 ± 1.3 | 26.7 ± 1.1 | 132 ± 1.9 |
| Samples | −Ecorr, mВ | Icorr, А/сm² | rcorr, mm/a | Tafel slopes, mV | |
| ba | bc | ||||
| Initial | 218.87 | 6.0461E−06 | 0.12294 | 834.37 | −361.68 |
| No. 1 | 132.17 | 3.5191E−07 | 0.0041284 | 379.43 | −86.935 |
| No. 2 | 52.177 | 4.2888E−07 | 0.0050313 | 220.49 | −359.68 |
| No. 3 | 44.49 | 8.663E−07 | 0.010163 | 966.84 | −170.35 |
