Influence of Zinc on Surface Treatments of Aluminium-Zinc Alloys A thesis submitted to the University of Manchester for the degree of Doctor of Philosophy in the Faculty of Engineering and Physical Sciences 2010 Marialuisa Gentile Corrosion and Protection Centre School of Materials 1 aaa 2 List of Contents List of Contents List of Figures................................................................................................................7 List of Tables................................................................................................................16 Abstract........................................................................................................................17 Declaration...................................................................................................................18 Copyright Statement.....................................................................................................19 Acknowledgements......................................................................................................20 Chapter 1 Introduction…………………………………………………………………............21 Overview......................................................................................................................21 Objectives………………….........................................................................................23 Chapter 2 Properties, Corrosion and Surface Treatments of Aluminium and Aluminium Alloys...........................................................................................................................25 Introduction..................................................................................................................25 Properties of Aluminium..............................................................................................26 The Al-H O Pourbaix Diagram....................................................................................27 2 Properties of Zinc.........................................................................................................29 The Zn-H O Pourbaix Diagram...................................................................................31 2 Aluminium Alloys........................................................................................................32 Classification System of Aluminium Alloys................................................................32 Metallurgy of Aluminium Alloys.................................................................................34 Effect of Composition and Microstructure on Corrosion Resistance of Aluminium Alloys...………………………………………………………………………………35 Properties of Al-Zn Alloy…..………………………………………………………..36 The Aluminium-Zinc Equilibrium Diagram…………………………………………36 Corrosion of Aluminium..............................................................................................37 Pitting Corrosion..........................................................................................................37 Theories of the Mechanism of Pitting Corrosion.........................................................41 Pitting Corrosion of Aluminium and its Alloys……………………………………...43 Surface Treatments of Aluminium…………………………..….................................45 3 List of Contents Mechanical Polishing...................................................................................................45 Electropolishing............................................................................................................45 Relationship Between Current and Voltage.................................................................46 Alkaline Etching...........................................................................................................48 Chapter 3 Oxides of Aluminium and Aluminium Alloys..........................................................61 Introduction..................................................................................................................61 Properties of Aluminium Hydroxide/Oxyhydroxides and Oxides …..........................61 Aluminium Trihydroxides……………………………………………........................62 Aluminium Oxide Hydroxides.....................................................................................63 Aluminium Oxide.........................................................................................................64 Anodic Oxides Formed by Anodic Polarization of Aluminium........... .......................65 Barrier Anodic Films....................................................................................................66 Porous-type Anodic Films........................................................................................... 67 Mechanisms of Ionic Transport through Oxide Films……………………………….69 The High Field Conduction Theory………………………………………………….69 Oxidation of Aluminium Alloys……………………………………………………...74 Enrichment of Aluminium Alloys…………………………………………………....75 Chapter 4 Experimental Procedure............................................................................................90 Introduction..................................................................................................................90 Materials.......................................................................................................................90 Surface Treatments.......................................................................................................91 Mechanical Polishing...................................................................................................91 Electropolishing...........................................................................................................91 Etching and Desmuting................................................................................................91 Anodizing……………………………………………………………………...……..92 Open Circuit Potential Responses………………………………………...…………92 Weight Loss Measurements………………………………………………………….93 Analytical Techniques...................................................................................,..............94 Rutherford Backscattering Spectroscopy (RBS)..........................................................94 Medium Energy Ion Scattering (MEIS)……………………………………………...94 4 List of Contents Glow Discharge Optical Emission Spectroscopy (GDOES)………………………....95 Scanning Electron Microscopy (SEM)…………………………………………….....95 Atomic Force Microscopy (AFM) and Interferometry…...……………………….....95 Electron Backscattered Diffraction (EBSD)………………………………………....97 Transmission Electron Microscopy (TEM)..................................................................97 Chapter 5 Influence of Surface Treatments on Zinc Enrichment in Al-Zn Alloys………..104 Introduction................................................................................................................104 Results........................................................................................................................105 RBS and MEIS Spectra…...………………………………………...........................105 GDOES Spectra……….…………………………….................................................107 Transmission Electron Microscopy............................................................................107 Etching Rate…………………………............................................................................108 Discussion..................................................................................................................108 Conclusions................................................................................................................111 Chapter 6 Influence of Zinc on the Surface Morphologies of Al-Zn Alloy...........................128 Introduction................................................................................................................128 Results........................................................................................................................129 Scanning Electron Microscopy (SEM) of Al-Zn Alloys ………..…….......................129 Potential-time Behaviour during Anodic Alkaline Etching………………………...131 Potential-time Behaviour during Etching in Alkaline Solution………………….....131 Discussion..................................................................................................................132 Conclusions................................................................................................................137 Chapter 7 Influence of Surface Pretreatments on Anodizing of Al-Zn Alloys.....................149 Introduction................................................................................................................149 Results…………………………………………………………………………...….149 Voltage-time Response of the Al-Zn Alloy...............................................................149 Scanning Electron Microscopy (SEM) of the Anodized Al-Zn Alloys………….…151 5 List of Contents Transmission Electron Microscopy of Anodized Al-Zn Alloys................................153 Discussion…………………………………………………………..........................153 Conclusions……………………………………………………………………........156 Chapter 8 Influence of Grain Orientation on Zinc Enrichment and Surface Morphologies of Al-Zn Alloys……………………………………..…….......................................165 Introduction................................................................................................................165 Results……………………………………................................................................166 FEG-SEM-EBSD.......................................................................................................166 RBS…………………………………………………………………………............167 MEIS………………………………………………………………………………..167 AFM and Trace Analysis………….……………………………….............................168 Interferometry………………………………………………………….....................170 Discussion…………………………………………………………………………..171 Dissolution of Al-Zn Alloys……………….………………………………………..171 Influence of Grain Orientation on Zinc Enrichment………………….....………….174 Conclusions………………………………………………………………………....176 Appendix A-RBS, MEIS and GDOES Spectra of Al-Zn Alloys………..………193 Appendix B-Surface Morphologies of Al-Zn Alloys in Rolled Conditions and Surface Pretreated....................................................................................................214 Appendix C-Potential Measurements during Alkaline Etching and Anodic Alkaline Etching of Al-Zn Alloys...……………….................................................224 Appendix D-RBS and MEIS Spectra of (225), (314) and (113)...........................226 Appendix E - Inverse Pole Figure Representing the Grain Analysed in the Step Height Measurements...................................................................………………...230 General Conclusions and Future Work.................................................................235 Bibliography.............................................................................................................238 6 List of Figures and Tables List of Figures Chapter 2 Figure 2.1/pag.50 FFC crystal structure of aluminium. Figure 2.2/pag.51 Al-H O Pourbaix diagram. 2 Figure 2.3/pag.52 Rages of aluminium hydroxide complexes in water. Figure 2.4/pag.53 Hexagonal close-packing structure of zinc. Figure 2.5/pag.54 Zn-H O Pourbaix diagram. 2 Figure 2.6/pag.55 Aluminium-Zinc equilibrium diagram. Figure 2.7/pag.56 Influence of temperature on pitting of aluminium. Figure 2.8/pag.57 Scheme of the autocatalytic process occurring in a corrosion pit. Figure 2.9/pag.58 Schematic illustration of surface wave and mound morphologies of electropolished aluminium surface. Figure 2.10/pag.59 Typical relationship between the current and the anode potential electropolishing of aluminium. Figure 2.11/pag.60 Rate of etching 99.5% aluminium caustic soda. Chapter 3 Figure 3.1/pag78. Structure of gibbsite. Figure 3.2/pag.79 Structures of boehmite and diaspore. Figure 3.3/pag.80 Schematic diagrams of growth of anodic alumina at high Faradic efficiency. Figure 3.4/pag.81 Schematic diagrams illustrating the incorporation of foreign species, derived from electrolyte ions, into anodic alumina films formed at high Faradic efficiency. Figure 3.5/pag.82 Schematic diagrams showing the development of a porous anodic film on aluminium. Figure 3.6/pag.83 Schematic representation of field assisted dissolution. Figure 3.7/pag.84 Structure of a porous film on pure aluminium. Figure 3.8/pag.85 Schematic diagrams showing the plan and cross-sectional views of pore and its adjacent cell formed in acid solution. 7 List of Figures and Tables Figure 3.9/pag.86 Potential energy (P.E.) of mobile ions vs distance with and without an applied field. Figure 3.10/pag.87 Schematic diagram of the mechanism of formation of the enriched layer. Figure 3.11/pag.88 Linear relationship between the amount of enrichment and the Gibbs free energy change for oxide formation per equivalent. Figure 3.12/pag.90 Schematic diagram of different model of enrichment of copper in aluminium copper alloys. Chapter 4 Figure 4.1/pag.98 Schematic diagram of the experimental arrangement for the electropolishing cell. Figure 4.2/pag.99 Schematic diagram of the apparatus used for alkaline etching. Figure 4.3/pag.100 Schematic diagram of the apparatus used for anodizing at constant current. Figure 4.4/pag.101 Schematic diagram of the apparatus used for corrosion potential measurements. Figure 4.5/pag.102 Schematic representation of the procedure employed in the measurement of the step heights. Chapter 5 Figure 5.1/pag.115 RBS spectrum of the Al-1at.%Zn alloy in the rolled condition. Figure 5.2/pag.116 RBS spectrum of the Al-1at.%Zn alloy after mechanical polishing. Figure 5.3/pag.117 RBS spectra of the Al-1at.%Zn alloy after alkaline etching in 0.5 M NaOH at 313K for 300 s. Figure 5.4/pag118. RBS spectrum of the Al-1at.%Zn alloy after etching under the anodic condition at 5 mA/cm2 in a solution of 0.5 M NaOH for 70 s at room temperature Figure 5.5/pag.119 RBS spectrum of Al-1at.%Zn alloy after electropolishing at 20V in a solution of perchloric/ethanol (1:4 v/v) for 180 s. 8 List of Figures and Tables Figure 5.6/pag.120 MEIS spectrum for Al-1at.%Zn alloy after etching under open circuit condition at 313 K in a solution of 0.5 M NaOH for 300 s. Figure 5.7/pag.121 MEIS spectrum for Al-1at.%Zn alloy after electropolishing at 20V in a solution of perchloric/ethanol (1:4 v/v) for 180 s. Figure 5.8/pag.122 Enrichment of zinc of the binary alloys after the following treatments: electropolishing at 20V for 180 s in perchloric acid/ethanol (1:4 v/v), etching in open circuit condition for 300 s in 20g/l NaOH solution, etching in anodic condition at 5 mA/cm2 for 70 s in 20 g/l NaOH solution. Figure 5.9/pag.123 GDOES spectrum for Al-1at.% Zn alloy after electropolishing at 20 V in a solution of perchloric/ethanol (1:4 v/v) for 180 s. FFiigguurree 55..1100//ppaagg..112244 TTrraannssmmiissssiioonn eelleeccttrroonn mmiiccrrooggrraapphh ooff tthhee uullttrraammiiccrroottoommeedd sseeccttiioonn ooff AAll--11..99aatt.. %%ZZnn aallllooyy aafftteerr eettcchhiinngg uunnddeerr ooppeenn cciirrccuuiitt ccoonnddiittiioonnss iinn 00..55 MM NNaaOOHH aatt 331133 KK ffoorr 330000 ss.. FFiigguurree 55..1111//ppaagg..112255 EEDDXX aannaallyyssiiss ooff tthhee AAll--11..99aatt.. %%ZZnn aallllooyy eettcchheedd uunnddeerr ooppeenn cciirrccuuiitt ccoonnddiittiioonnss iinn 00..55 MM NNaaOOHH aatt 331133 KK ffoorr 330000.. FFiigguurree 55..1122//ppaagg..112266 SSppeecciimmeenn ooff tthhee AAll--11..99aatt..%%ZZnn aallllooyy eelleeccttrrooppoolliisshheedd iinn a solution of perchloric/ethanol (1:4 v/v) aatt 2200VV ffoorr 118800ss.. FFiigguurree 55..1133//ppaagg..112277 SSppeecciimmeenn ooff tthhee AAll--11..99aatt..%%ZZnn aallllooyy eelleeccttrrooppoolliisshheedd iinn a solution of perchloric/ethanol (1:4 v/v) aatt 2200VV ffoorr 118800ss.. Chapter 6 Figure 6.1/pag.141 Secondary electron micrographs at different magnifications of the Al-1at.%Zn alloy specimen in the rolled condition. Figure 6.2/pag.142 Secondary electron micrographs at different magnification of the Al-1at.%Zn alloy after mechanical polishing. Figure 6.3/pag.143 Secondary electron micrographs at diverse magnification of Al- 1at.%Zn alloy of the specimen electropolished at 20V in a solution of perchloric/ethanol (1:4 v/v) for 180 s. Figure 6.4/pag.144 Secondary electron micrographs at diverse magnification of Al- 1at.%Zn alloy of the specimen anodic alkaline etched at 5 mA/cm2 in a solution of 0.5 M NaOH for 70 s at room temperature. 9 List of Figures and Tables Figure 6.5/pag.145 Secondary electron micrographs at diverse magnification of Al- 1at.%Zn alloy of the specimen specimen etched in open circuit condition at 313 K in a solution of 0.5 M NaOH for 300 s. Figure 6.6/pag.146 Energy dispersive X-ray spectroscopy of a particle on the surface of the alkaline etched specimens. Figure 6.7/pag.148 Potential-time behaviour during anodic alkaline etching of Al- 1at.%Zn alloy in alkaline solution 0.5 M NaOH at T = 298 K for 70 s. Figure 6.8/pag.147 Potential-time behaviour during anodic alkaline etching of aluminium (99.99wt.%) in alkaline solution 0.5 M NaOH at T = 298 K for 70 s. Figure 6.9/pag.149 Open circuit potential transient following alkaline etching of Al- 1at.%Zn alloy in 0.5 M NaOH at T = 313 K for 300 s. Figure 6.10/pag.150 Secondary electron micrographs of a etching of pure aluminium and Al-1at.%Zn alloy in alkaline solution 0.5 M NaOH at 313 K for 300 s. Chapter 7 Figure 7.1/pag.158 Voltage-time response of Al-1at.%Zn alloy anodized in 0.1 M ammonium pentaborate at 5 mA/cm2 until the final potential of 200V. The alloy before anodizing was in rolled condition and surface treated with the following treatments: electropolishing at 20V for 180 s in perchloric acid/ethanol (1:4 v/v), alkaline etching in 0.5 M NaOH solution for 300s, anodic alkaline etching at 5 mA/cm2 in 0.5 M NaOH solution for 70s. Figure 7.2/pag.159 Secondary electron micrograph at different magnification of the Al-1at.%Zn alloy in rolled condition and anodized in 0.1M ammonium pentaborate at 5 mA/cm2 to 200V. Figure 7.3/pag.156 Secondary electron micrograph at different magnifications of Al- 1at.%Zn alloy mechanically polished and subsequently anodized in 0.1M ammonium pentaborate at 5 mA/cm2 to 200V. Figure 7.4/pag.157 Secondary electron micrograph at different magnifications of the Al- 1at.%Zn alloy electropolished in at 20V for 180 s in perchloric acid/ethanol (1:4 v/v) and anodized in 0.1M ammonium pentaborate at 5 mA/cm2 to 200V. Figure 7.5/pag.158 Secondary electron micrograph at different magnifications of the Al-1at.%Zn alloy alkaline etched in 0.5 M NaOH solution for 300s and anodized in 10
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