Impact of Corrosive Liquid on Trivalent Chromium over Aluminium Alloys ()
1. Introduction
Aluminium alloys are commonly used material in aviation and aerospace industries due to its lightweight and high strength in nature [1] . AA7075, AA6063 and AA6082 alloys are widely used for space sectors. Chromate conversion coating technique is used for passivating these aluminium alloys, to prevent material getting corroded [2] . Hexavalent chromium ions (Hex chrome or Cr6+) were employed under chromate conversion coating till date. Hex chrome is banned due to its carcinogenic and hazard nature by Registration, Evaluation, Authorisation and Restriction of Chemicals (REACH) and Restriction of Hazardous Substance (RoHS) regulation with sunset date of September 2017. Industry and research groups are focused towards replacement of traditional Cr6+ chromating [3] . In this regard, trivalent chromium (Cr3+) ions seem to be the best alternative due to its low toxicity. Moreover, trivalent chromium ions also exhibit good corrosion resistance in tropical environments because most of the launching base of Europe Space Agency (ESA) is located at high humid, high temperature and salty atmosphere [4] .
The promising result by Cr3+ in atmospheric condition is now evaluated under space qualification programs. So, this paper evaluates suitability of trivalent chromium coating in accordance to ASTM and ISO standards. The chromium treatment using trivalent chromium bath containing of zirconium hexafluoride and trivalent chromium salts [5] . In literature, corrosion of coating over AA2024 alloy has been studied in detail. The results indicated that local corrosion starts with development of corrosion rings that evolves hydrogen gas [6] . Most of previous studies are related to corrosion on AA2024 alloy under SO2 atmosphere and surface of corroded area had been analyzed using surface image instruments.
The variation in corrosion inhibition property of Cr3+ among different alloys has not been studied in detail. The NSS conducted over three-alloy surface as mentioned earlier, at the University of Miskolc on salt spray test chamber signifies importance of substrate in coating formation. In present study ICP-OES have been employed to analyze degradation of coated and non-coated aluminium alloy in 0.85 M of NaCl corrosive solution that is recommended for NSS test by ASTM B117 standard. The work reveals that the trivalent chromium coating (TCC) differs its property from each type alloy which depends on their alloying elements of the base metal. The salt spray showed positive result only for aluminium that has low alloying elements in its elemental constituents.
2. Experimental Phase
2.1. Specimen and Preparation
The metal samples with the composition as given in Table 1 were obtained as 90 × 70 mm dimension with 4mm thick sheets. The received specimens were initially cleaned with detergent and rinsed with isopropyl alcohol, ethanol and acetone for few seconds. The degreased 6063 and 6082 samples were etched with 5 Vol∙% of NaOH for 180 s and desmutted with H2SO4 solution of 17 v/v % for 180 s. Both pre-treatments were carried out at room temperature. In the case of 7075 samples pre-treatments proceeds as follows: 1) etching in NaOH at 5Vol% for 180 s at 60˚C; 2) desmutting using 50 v/v % H2SO4 for 180 s at room tem-
Table 1. Elemental composition of alloy (wt. %).
perature. All samples were thoroughly rinsed using deionised water after each pre-treatment.
All the three oxide free alloy samples were treated at various immersion times such as 60, 120, 300 and 600 secs at 40˚C using SurTec 650 bath with chemical composition as mention in datasheet [7] under pH of 3.8 followed by DI (Deionised) water rinsing. After coating, NSS test samples were rinsed with deionised water and dried at room temperature for 24 hours. Coating mass measured on certain samples after three hours drying, as per ISO 3892:2000 standard. The standard insist that samples must immersed in dilute nitric acid for 120 secs to remove deposition of Cr3+ coating from aluminium alloy. The mass of the samples was measured before and after removal of coating [8] . Some of the samples from coated and non-coated AA7075 were immersed in 0.85 M of NaCl solution as recommended by ASTM B117 standard for three consecutive days to understand degradation process of trivalent chromium coating and substrate.
2.2. Salt Spray Test
The salt spray test is standardized method used to test corrosion resistance of material and surface coating. The ASTM B117 standard for operating salt fog or salt spray cabinet is widely accepted by several space industries including NASA and ESA [9] . This test is operated by placing samples of various size and shape inside the chamber as shown in Figure 1 which is exposed to saline fog or spray that is even distributed among the samples inside B117 testing chamber. The pH and temperature of salt fog is monitored continuously throughout the test. The samples are examined visually to measure the integrity of alloy coating. Comparisons of pre-and post-testing images under normal photographic picture and visual inspection gives the degradation of samples under salt atmosphere. The variation in salt spray test results highly depends on the type of material to be tested. In case of aluminium alloy if the coated material exhibits any kinds of pits under visual inspection, tested sample are considered as failed per standard mentioned above. The most common tests for aluminium based material is neutral salt spray test which reflects that fact that this type of test solution is prepared to a neutral pH of 6.5 to 7.2.
2.3. ICP-OES
Inductively Coupled Plasma Optical Emission Spectroscopy is an analytical
Figure 1. Samples inside salt spray chamber.
technique used for the detection of trace elements. It works on basic principle that the samples at high temperature plasma up to 8000 Kelvin converted to free, excited, or ionized ions. The excited atoms emit radiations when it goes back to ground state. Detectors optically measure the emitted characteristics radiation and intensity [10] . The sample preparation is most important technique that to be considered before any elemental analysis because the solution before test must be free from any impurities to avoid error in detection of elements. To predict behaviour of TCC coating in corrosive liquid the coated sample was immersed in 0.85 M of NaCl solution for three days in closed condition. The NaCl solution was prepared form nano pure water supplied by VMR International Kft [11] . The elements inside corrosive liquid from trivalent chromium coating and its substrates is analysed by ICP-OES at department of chemistry in University of Miskolc.
2.4. Secondary Neutral Mass Spectroscopy (SNMS)
Elemental depth profile of coatings on various substrates was performed by an INA-X (SPECS Gmbh Berlin) type SNMS system at ATOMKI in Debrecen, Hungary. The device uses an Electron Cyclotron Wave Resonance (ECWR) plasma as an ion source and post ionization medium with sputtering energies of a few 100 eV. The SNMS is equipped with a quadrupole type mass spectrometer up to 340 amu for detecting elements. Basically, the samples were bombarded and post ionized using an inductively coupled low pressure radio frequency Ar discharge. The Ar ions were extracted from the plasma to sputter the sample surface with a high frequency negative bias on the sample. Energy dispersive ion optics discriminated the residual ions. The bombarding energy of Ar ions for TCC coated sample was around 350 eV with plasma pressure of 1.5 mbar. The elemental composition of the coating was determined using sensitivity factors of the constituents. The sputtering time was converted into a depth by calibration of sputtering rates with a profilometer and by taking in to account sputtering yield changes during profiling and changes in the layer density [12] . The depth scale was fixed by accepting the nominal surface roughness of the sample before and after measurements.
4. Results and Discussion
4.1. Elemental Analysis of Coating
The SNMS mass spectroscopy analysis of trivalent chromium coating over three different materials as mention earlier shows significant proof that coating consist of similar species independent of substrate on which coating is formed. The mass spectrum graph from SNMS reveals that Zr, Cr, Al, F, O atoms are present inside coating that is in accordance with previous work by Manchester group [13] possibly due to usage of the same SurTec 650 solution as shown in Figure 2 In general, elemental analysis of coating can be made by XPS (X-ray Photoelectron Spectroscopy). An XPS analysis published in literature also revealed that coating consist of AlF3, Al2O3, Cr(OH)3, ZrO2 and ZrF4 species [14] .
Figure 2. SNMS Elemental analysis of chromate coating.
4.2. NSS Test Results
The following images are the samples of AA7075, AA6063 and AA6082 after salt spray test. The images represent two non-coated (left) and two coated samples (right) with 168 Hrs. of exposure time.
The salt spray test result show that AA7075 alloy is not protected by trivalent chromium. The coating over AA6082 and AA6063 seems to have strong bonding towards substrate that is enough to provide corrosion resistance for 168 Hrs. in salt spray chamber. However, under same coating condition surface of AA7075 alloy samples is affected by pitting corrosion. Considering AA7075 alloy, it is evident from literature pretreatments that had been used for treating 7xxx alloy samples is not suitable enough due to its high copper and zinc content. The use of inhibited alkaline solution that is sodium hydroxide is not recommended for high strength alloy like 7xxx and 2xxx series alloy in certain aged temper because of the danger of intergranular attack [15] . This is evident from experimental series that NaOH alkaline solution for removal of aluminium oxide causes more pit formation in comparison with other pretreatment solution. Once sample is taken out from NaOH bath it turns into brown color that significance presence of copper and zinc content on top of alloy after removal of oxide layer. Inside the bath aluminium oxide layer is completely removed from surface of the alloy and leaves bare metal. Under bath 2, the 50% of H2SO4 solution is not suitable enough for dissolving all the copper ions that were present on surface of alloy sample. Either the sample immersion time or concentration of the solution should have been increased to get optimum result. While considering coating surface morphology of AA7075, it is clear from previous SNMS evaluation that the coating is non-uniform on surface of alloy sample. This non-uniformity of Cr3+ inside pits and region where copper content is high might be the possible reason for failure of this alloy sample as shown Figure 3. Even though this alloy series is dominated by zinc as a major constituent but only copper ions shows susceptible reason for the failure.
4.3. Elemental analysis by ICP-OES
From NSS test (Table 2), only AA 7075 alloy have been selected for the analysis in corrosive liquid.
The elemental analysis Table 3 indicated that almost all elements from coating and substrate is dissolved into strong NaCl solution.
The formation of bonding between ions inside chromate solution over AA7075 alloy is weak, to withstand concentrated strong base solution. In comparison between zinc and copper, Cu ions has higher electrode potential as per Table 4 seems to be root cause for breaking of bonds between coating and its substrates. Once copper breaks its bonds followed by other ions inside alloying elements. This can be possible reason for pitting corrosion of AA7075 alloy inside air chamber. The thickness of coating does have much influence on corrosion resistance property of coating because sample exhibit same corrosive state under visual inspection. However, for thick coating number of ions dissolved in
Figure 3. Surface of AA7075 alloy with current pre-treatment with enriched copper ions on surface of aluminium (left) and required TCC for better corrosion protection (right).
Table 3. Elements detected in corrosive liquid.
Table 4. Standard electrode potential of metals in NaCl solution [16] .
NaCl solution is less compared to thin coating. To achieve coating maximum protection and stabilized structure of coating both ageing and post water immersion technique must be implied applied for this alloy. The ageing is a process
Figure 4. Result of untreated and treated AA7075 alloy with various coating mass (0.16 g/m2) left and (0.36 g/m2) right.
Figure 5. Result of untreated and treated AA6082 alloy with various coating mass (0.12 g/m2) left and (0.46 g/m2) right.
Figure 6. Result of untreated and treated AA6063 alloy with various coating mass (0.15 g/m2) left and (0.3 g/m2) right.
under which coating is dried for certain period to achieve stabilized structure. Post water treatment is a technique in which freshly coated layer is immersed immediately after sample preparation in to water for few seconds to obtain optimized coating state [17] . The corresponding experimental results will be discussed in our next paper using SNMS technique [18] .
5. Conclusions
・ The trivalent chromium coating is not effective on highly alloyed aluminium, corrosion resistance property of coating on AA7075 alloy is affected by pitting corrosion compared to other two alloys.
・ The NSS test result also proves that thickness of the layer does not have any influence corrosion resistance property of trivalent chromium coating. How ever, ICP-OES revealed some differences between thin and thick coating films, so there are possibilities for differences, but duration or checking frequency of the salt spray test was not enough.
・ The degradation of trivalent chromium coating along with substrate in corrosive liquid by ICP-OES indicated that both coating and substrate are involved in corrosion process.
・ The elements dissolved in to salt solution reveals weak bonding of coating towards substrates. The chromium coating over AA7075 alloy has weak bonds compared to AA6063 and AA6082 series. The alloying elements such as zinc and copper are removed from substrate by corrosive solution.
The copper ions are suspected to be major reason for failure in corrosion resistance of Cr3+ over AA7075 due to high standard electrode potential in NaCl solution
Acknowledgements
The authors are thankful to A. Csík and K. Vad (ATOMKI) for the SMNS measurement, furthermore for ICP-OES measurement to O. Bánhidi. This project was financed by ESA, Contract No.4000114580/15/NL/ND.