Thin films produced on 5052 aluminum alloy by plasma electrolytic oxydation with Red Mud-containing Electrolytes

Sottovia, Lívia; Antunes, Maria Lúcia Pereira; Antonio, César Augusto; Rangel, Elidiane Cipriano; Cruz, Nilson Cristino da

doi:10.1590/1516-1439.283414

Abstract

In this paper, we propose the production of ceramic protective thin films by plasma electrolytic oxidation using red mud-containing electrolytes. The treatments were performed through the application of pulsed voltage (600 V, 200 Hz) during 300 seconds to aluminum samples immersed in electrolytic solutions with 5 g of red mud per liter of distilled water. The coatings were characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), X-ray energy dispersive spectroscopy (EDS) and contact angle and surface energy measurements. The final current density during the experiments was 0.05 A/cm² and films as thick as 9.0 µm have been obtained. XRD patterns have clearly shown the incorporation of species from the red mud on the coating.

plasma electrolytic oxidation; ceramic coatings; red mud

ARTICLES PRESENTED IN THE 4TH TECHNICAL METTING OF MATERIALS SCIENCE AND TECHNOLOGY POST-GRADUATION PROGRAM OF UNESP, POSMAT

Thin films produced on 5052 aluminum alloy by plasma electrolytic oxydation with Red Mud-containing Electrolytes

Lívia Sottovia^* * e-mail: liviasottovia@gmail.com ; Maria Lúcia Pereira Antunes; César Augusto Antonio; Elidiane Cipriano Rangel; Nilson Cristino da Cruz

Universidade Estadual Paulista - UNESP, Av. Três de Março, 511, CEP 18087-180, Sorocaba, SP, Brazil

ABSTRACT

In this paper, we propose the production of ceramic protective thin films by plasma electrolytic oxidation using red mud-containing electrolytes. The treatments were performed through the application of pulsed voltage (600 V, 200 Hz) during 300 seconds to aluminum samples immersed in electrolytic solutions with 5 g of red mud per liter of distilled water. The coatings were characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), X-ray energy dispersive spectroscopy (EDS) and contact angle and surface energy measurements. The final current density during the experiments was 0.05 A/cm² and films as thick as 9.0 µm have been obtained. XRD patterns have clearly shown the incorporation of species from the red mud on the coating.

Keywords: plasma electrolytic oxidation, ceramic coatings, red mud

1. INTRODUCTION

Aluminum is widely used in aerospace, automotive, marine and domestic industries, due to its lightness, durability, thermal and electrical conductivity, strength, ductility and weldability^1,2. It is a very chemically active material, despite the passivating alumina film that is easily formed on its surface when in contact with oxygen³. However, some pollutants can lead to corrosion and, consequently, the reduction of mechanical strength¹. In this context, ceramic coatings are potentially a good solution to increase the resistance to corrosion and wear of metal surfaces⁴, increasing their useful lives.

The plasma electrolytic oxidation (PEO) is a technique that combines atmospheric arc plasmas in an aqueous solution with the known processes of metal oxidation by electrolysis⁵. Such technique allows the production of oxide films on lightweight metals, such as aluminum, titanium and magnesium. Since the process involves the oxidation of the substrate and the incorporation of species in the electrolytic solution, the properties of the coatings depend on the combination of the substrate and the electrolyte solution. In particular, for the production of aluminum oxide coatings, rapid dissolution of aluminum could be achieved with NaCl, NaOH, NaClO₃, HCl, and NaNO₃ solutions⁶.

The red mud (RM) is a residue from the clarifying Bayer process. It is a highly alkaline insoluble solid containing significant amount of elements such as iron, silicon, titanium and aluminum^7-9. Such characteristics suggest the red mud to be considered as a promising material to be used in electrolyte solutions for coating of aluminum by PEO since the incorporation of such valuable elements in the coating may contribute to the improvement of wear and corrosion resistances of the substrates. The red mud has been studied for the construction industry, adsorbent metals and organic materials and CO₂ capture⁷. In recent years it has been studied as ceramic films for protecting metals^10-13.

In this paper, we have studied the production and characterization of ceramic films produced by plasma electrolytic oxidation of red mud-based electrolytes as a possible value added destination to this residue.

2. MATERIAL AND METHODS

2.1. Red mud preparation and characterization

The red mud used in this study was collected in wet form from an industrial bauxite processing plant, located in Alumínio-SP, Brazil. Red mud samples were dried at 50 °C in a muffle for 24 hours, and then they were macerated and stored. The morphology of red mud samples were observed by Scanning Electron Microscopy (SEM) using a JEOL JSM-6010LA microscope fitted with an X-ray energy dispersive spectrometer unit (EDS). Mineral composition was determined by X-ray Diffraction (XRD), using a Panalytical X'Pert powder diffractometer operating at 45 kV, 40 mA with CuKα radiation.

2.2. Electrolytic solution and substrate preparation

The electrolytic solution was prepared with 5 g/ L of red mud, potassium hydroxide and distilled water. The solution had a pH of 11. 5052 aluminum alloy, containing 0.25%wt Si, 0.40%wt Fe, 0.10%wt Cu, 0.10%wt Mn, 2.2-2.8%wt Mg, between 0.15 and 0.35%wt Cr, 0.10%wt Zn, 0.15%wt of other elements¹⁴ was used as substrate. The dimension of substrates was standardized at 25 × 25 × 1.3 mm³. The samples were sandpapered, polished and cleaned with ultrasonic baths in distilled water, acetone and isopropyl alcohol.

2.3. Deposition and characterization of ceramic films of red mud

The samples immersed in the electrolytic solution were connected to the positive terminal of a pulsed power supply (MAO Power Supply) operating at 600 V, 200 Hz, 60% of duty cycle, during 300 seconds. After the treatments, the samples were dried with a hot air gun and analyzed by contact angle and surface energy (Ramé-Hart, model number 100-000), SEM, EDS, XRD and the coating thicknesses were measured at least ten times in four different positions using the eddy current method (Politerm microprocessor CM-8825FN). Distilled water was used as test liquid in contact angle (CA) measurements. Three drops were placed on different positions in each sample and at least ten measurements of each drop were performed immediately after the treatments and once in a week during the first month after the treatment, every fifteen days during the second month and, from then on, every thirty days. The procedure was employed to evaluate the surface energy. However, in that case, the probe liquid was diiodomethane.

3. RESULTS AND DISCUSSION

3.1. Red mud characterization

As one can observe in Figure 1, which shows a SEM micrograph of the dried RM, the powder is constituted by particles of different sizes and shapes, some of them are smaller than 5 µm in diameter and without any regular pattern.

EDS spectra were taken in six randomly chosen points indicated in Figure 2 and the elements detected in each point are shown in Table 1.

Thumbnail

Iron and aluminum oxides are more frequent and with higher proportions, although silicon is present in all analyzed points. The smaller and more rounded particles are recurrent when there are higher proportions of iron, and the larger and more irregular particles contain higher percentage of aluminum. These results are in good agreement with the literature about red mud⁷.

The mineralogy of the red mud was analyzed by XRD and it complies with the literature^7,15. In the XRD patterns of red mud given in Figure 3, it can be observed peaks corresponding to sodalite (NaAlSi₄O₁₂Cl), gibbsite (Al(OH)₃), goethite (FeO(OH)), hematite (Fe₂O₃), kaolinite (Al₆Si₂O₂-(OH)₄), calcite (CaCO₃), quartz (SiO₂) and perovskite (CaTiO₃). Hematite, perovskite, goethite and gibbsite are the main components in red mud.

3.2. Characterization of red mud coatings

Figure 4 shows the average current density, ρ_I, as a function of treatment time. Some authors¹⁶ consider the current density as one of the most important parameter in a PEO process because, according to the first Faraday law, the coating growth under certain conditions is directly proportional to the electric charge across the solution¹⁷. Therefore, the decrease in ρ_I observed in Figure 4 suggests the decrease of the deposited mass during the treatment. The average film thickness attained after 300 s of treatment was 8.9 (±3.3) µm.

The contact angle and surface energy results are presented in Figures 5 and 6, respectively.

The contact angle and the total surface energy, E_S, of the as-received aluminum sample were 64.9° and 50.3 Dyn/cm, respectively. The contact angle, that was too low to be measured at the first day after the treatment, increased continuously reaching 82° after aging for eight weeks. The total surface energy has increased to 72.0 Dyn/cm after the first week and then decreased to 42.0 Dyn/cm, reflecting the decreasing of the polar component of E_S.

Figure 7 presents typical SEM micrographs of the coatings.

The images show a porous surface with plateaus and granular parts. As it can be observed, the porous diameters are typically smaller than 5 µm.

In Figure 7b, one can note the presence of smoother or nodular regions, which are indicative of particle coalescence. It is interesting to point out that although such structures are normally observed after exposing the material to very high temperatures¹⁸, above its melting point, they have been formed with treatments in electrolytes whose temperatures have not exceeded 90 °C.

Table 2 presents the atomic composition as determined by EDS spectra collected in four points chosen randomly over the entire sample surface. It is worthy to note that the coalesced regions are constituted mainly by aluminum, suggesting the alloying of the substrate with electrolyte species.

Thumbnail

In addition, some elements, such as sulfur, phosphorous, calcium and titanium, present in the red mud have not being incorporated to the coating, indicating that physicochemical effects, rather than purely amalgamation, are responsible for the growth and the properties of the coatings.

The X-ray patterns of aluminum substrate and substrate after PEO processing are given in Figure 8. Although only aluminum is observed on the diffractogram of the bare substrate, it can be observed a plentitude of species such as sodalite, hematite, calcite, quartz, gibbsite, goethite and perovskite on the X-ray pattern of the coated aluminum. Furthermore, other mineralogical components, such as titanium, iron, aluminum oxide and sodium manganese oxide, were also identified. Since some of these elements have not been detected by EDS, this result indicates that they are present in deeper regions not assessed by EDS.

4. CONCLUSION

It has been demonstrated the possibility to produce complex ceramic coatings by plasma electrolytic oxidation of aluminum substrates using red mud based-electrolytes. Coatings as thick as 9 µm have been grown after 300 s of treatment. The aging in air during 8 weeks caused the water contact angle, initially null, to increase up to 82°. Such decrease in surface hydrophilicity was a consequence of the decrease of the density of polar groups on the surface, as evaluated with surface energy measurements. It has been detected the formation of species such as sodalite, hematite, calcite, quartz, goethite, gibbsite and perovskite, which are supposed to confer enhanced wear and corrosion resistances to the surfaces.

ACKNOWLEDGEMENTS

The authors would like to thank CAPES and FAPESP, through grant 2011/23733-8, for financial support.

Received: April 3, 2014

Revised: December 18, 2014

1. Abreu F. Avaliação da resistência à corrosão da liga de alumínio 6101 após diferentes tratamentos térmicos de precipitação. Corrosão e Protecção de Materiais 2012; 31(3-4):65-70.
2. Associação Brasileira do Alumínio - ABAL. Alumínio São Paulo. Available from: <http://www.abal.org.br/>. Access in: 19/02/2013.
3. Oliveira CR. Alteração das propriedades superficiais do alumínio via eletrólise a plasma. [Dissertation]. Sorocaba: Universidade Estadual Paulista; 2010.
4. Gu WC, Lv G-H, Chen H, Chen G-L, Feng W-R and Yang S-Z. Characterisation of ceramic coatings produced by plasma electrolytic oxidation of aluminium alloy. Materials Science and Engineering 2007; 447(1-2):158-162. http://dx.doi.org/10.1016/j.msea.2006.09.004
5. Yerokhin AL, Snizhko LO, Gurevina NL, Leyland A, Pilkington A and Matthews A. Spatial characteristics of discharge phenomena in plasma electrolytic oxidation of aluminium alloy. Surface and Coatings Technology 2004; 177-178:779-783. http://dx.doi.org/10.1016/j.surfcoat.2003.06.020
6. Yerokhin AL, Nie X, Leyland A, Matthews A and Dowey SJ. Plasma electrolysis for surface engineering. Surface and Coatings Technology 1999; 122(2-3):73-93. http://dx.doi.org/10.1016/S0257-8972(99)00441-7
7. Antunes MLP, Couperthwaite SJ, da Conceição FT, Costa de Jesus CP, Kiyohara PK, Coelho ACV, et al. Red mud from brazil: thermal behavior and physical properties. Industrial & Engineering Chemistry Research 2012; 51(2):775-779. http://dx.doi.org/10.1021/ie201700k
8. Zhang N, Sun H, Liu X and Zhang J. Early-age characteristics of red mud-coal gangue cementitious material. Journal of Hazardous Materials 2009; 167(1-3):927-932. http://dx.doi.org/10.1016/j.jhazmat.2009.01.086 PMid:19237241
9. Wang S, Ang HM and Tadé MO. Novel applications of red mud as coagulant, adsorbent and catalyst for environmentally benign processes. Chemosphere 2008; 72(11):1621-1635. http://dx.doi.org/10.1016/j.chemosphere.2008.05.013 PMid:18558418
10. Jayasankar K, Ray PK, Chaubey AK, Padhi A, Satapathy BK and Mukherjee PS. Production of pig iron from red mud waste fines using thermal plasma technology. International Journal of Minerals, Metals and Materials 2012; 19(8):679-684. http://dx.doi.org/10.1007/s12613-012-0613-3
11. Sutar H. Morphology and solid particle erosion wear behavior of red mud composite coatings. Natural Science 2012; 4(11):832-838. http://dx.doi.org/10.4236/ns.2012.411111
12. Rath SS, Pany A, Jayasankar K, Mitra AK, Kumar CS, Mukherjee PS, et al. Statistical Modeling Studies of Iron Recovery from Red Mud Using Thermal Plasma. Plasma Science And Technology 2013; 15(5):459-464. http://dx.doi.org/10.1088/1009-0630/15/5/13
13. Satapathy A. Characterization of plasma sprayed pure red mud coatings: an analysis. American Chemical Science Journal 2013; 3(2):151-163. http://dx.doi.org/10.9734/ACSJ/2013/3218
14. Milan MT. Metais: uma visão objetiva São Carlos: Suprema; 2004.
15. Rivas Mercury JM, Cabral AA, Paiva AEM, Angélica RS, Neves RF and Scheller T. Thermal behavior and evolution of the mineral phases of Brazilian red mud. Journal of Thermal Analysis and Calorimetry 2011; 104(2):635-643. http://dx.doi.org/10.1007/s10973-010-1039-7
16. Guan YJ, Xia Y and Li G. Growth mechanism and corrosion behavior of ceramic coatings on aluminum produced by autocontrol AC pulse PEO. Surface and Coatings Technology 2008; 202(19):4602-4612. http://dx.doi.org/10.1016/j.surfcoat.2008.03.031
17. Halliday D, Resnick R and Walker J. Fundamentos de Física 3 6rd ed. Rio de Janeiro: LTC; 1996.
18. Santos PS, Santos HS and Toledo SP. Standard transition aluminas: electron microscopy studies. Materials Research 2000; 3(4):104-114. http://dx.doi.org/10.1590/S1516-14392000000400003

*

e-mail:

liviasottovia@gmail.com

Publication Dates

Publication in this collection
10 Feb 2015
Date of issue
Dec 2014

History

Received
03 Apr 2014
Accepted
18 Dec 2014

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Abreu F. Avaliação da resistência à corrosão da liga de alumínio 6101 após diferentes tratamentos térmicos de precipitação. Corrosão e Protecção de Materiais 2012; 31(3-4):65-70.

[2] 2. Associação Brasileira do Alumínio - ABAL. Alumínio São Paulo. Available from: <http://www.abal.org.br/>. Access in: 19/02/2013.

[3] 3. Oliveira CR. Alteração das propriedades superficiais do alumínio via eletrólise a plasma. [Dissertation]. Sorocaba: Universidade Estadual Paulista; 2010.

[4] 4. Gu WC, Lv G-H, Chen H, Chen G-L, Feng W-R and Yang S-Z. Characterisation of ceramic coatings produced by plasma electrolytic oxidation of aluminium alloy. Materials Science and Engineering 2007; 447(1-2):158-162. http://dx.doi.org/10.1016/j.msea.2006.09.004

[5] 5. Yerokhin AL, Snizhko LO, Gurevina NL, Leyland A, Pilkington A and Matthews A. Spatial characteristics of discharge phenomena in plasma electrolytic oxidation of aluminium alloy. Surface and Coatings Technology 2004; 177-178:779-783. http://dx.doi.org/10.1016/j.surfcoat.2003.06.020

[6] 6. Yerokhin AL, Nie X, Leyland A, Matthews A and Dowey SJ. Plasma electrolysis for surface engineering. Surface and Coatings Technology 1999; 122(2-3):73-93. http://dx.doi.org/10.1016/S0257-8972(99)00441-7

[7] 7. Antunes MLP, Couperthwaite SJ, da Conceição FT, Costa de Jesus CP, Kiyohara PK, Coelho ACV, et al. Red mud from brazil: thermal behavior and physical properties. Industrial & Engineering Chemistry Research 2012; 51(2):775-779. http://dx.doi.org/10.1021/ie201700k

[8] 8. Zhang N, Sun H, Liu X and Zhang J. Early-age characteristics of red mud-coal gangue cementitious material. Journal of Hazardous Materials 2009; 167(1-3):927-932. http://dx.doi.org/10.1016/j.jhazmat.2009.01.086 PMid:19237241

[9] 9. Wang S, Ang HM and Tadé MO. Novel applications of red mud as coagulant, adsorbent and catalyst for environmentally benign processes. Chemosphere 2008; 72(11):1621-1635. http://dx.doi.org/10.1016/j.chemosphere.2008.05.013 PMid:18558418

[10] 10. Jayasankar K, Ray PK, Chaubey AK, Padhi A, Satapathy BK and Mukherjee PS. Production of pig iron from red mud waste fines using thermal plasma technology. International Journal of Minerals, Metals and Materials 2012; 19(8):679-684. http://dx.doi.org/10.1007/s12613-012-0613-3

[11] 11. Sutar H. Morphology and solid particle erosion wear behavior of red mud composite coatings. Natural Science 2012; 4(11):832-838. http://dx.doi.org/10.4236/ns.2012.411111

[12] 12. Rath SS, Pany A, Jayasankar K, Mitra AK, Kumar CS, Mukherjee PS, et al. Statistical Modeling Studies of Iron Recovery from Red Mud Using Thermal Plasma. Plasma Science And Technology 2013; 15(5):459-464. http://dx.doi.org/10.1088/1009-0630/15/5/13

[13] 13. Satapathy A. Characterization of plasma sprayed pure red mud coatings: an analysis. American Chemical Science Journal 2013; 3(2):151-163. http://dx.doi.org/10.9734/ACSJ/2013/3218

[14] 14. Milan MT. Metais: uma visão objetiva São Carlos: Suprema; 2004.

[15] 15. Rivas Mercury JM, Cabral AA, Paiva AEM, Angélica RS, Neves RF and Scheller T. Thermal behavior and evolution of the mineral phases of Brazilian red mud. Journal of Thermal Analysis and Calorimetry 2011; 104(2):635-643. http://dx.doi.org/10.1007/s10973-010-1039-7

[16] 16. Guan YJ, Xia Y and Li G. Growth mechanism and corrosion behavior of ceramic coatings on aluminum produced by autocontrol AC pulse PEO. Surface and Coatings Technology 2008; 202(19):4602-4612. http://dx.doi.org/10.1016/j.surfcoat.2008.03.031

[17] 17. Halliday D, Resnick R and Walker J. Fundamentos de Física 3 6rd ed. Rio de Janeiro: LTC; 1996.

[18] 18. Santos PS, Santos HS and Toledo SP. Standard transition aluminas: electron microscopy studies. Materials Research 2000; 3(4):104-114. http://dx.doi.org/10.1590/S1516-14392000000400003

Brasil

Brasil

Thin films produced on 5052 aluminum alloy by plasma electrolytic oxydation with Red Mud-containing Electrolytes

Abstract

Publication Dates

History