Surface Changes during A.C. Etching of Aluminum

Dyer, C. K.; Alwitt, Robert S.

doi:10.1149/1.2127408

Cited by 75 publications

(71 citation statements)

References 2 publications

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“…[22][23][24][25] In contrast, AC etching in the similar HCl solutions produces a rough etched layer comprising interconnected cubic pits. [26][27][28][29] The size of the cubic pits is usually submicrometers. In this study, more simple chemical etching has been used.…”

Section: Surface Geometrymentioning

confidence: 99%

Fabrication of superoleophobic hierarchical surfaces for low-surface-tension liquids

et al. 2014

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This study demonstrates the fabrication of hierarchical surfaces with super -repellency even for low-surface-tension liquids, including octane (surface tension of 21.7 mN m −1 ). Dual-pore surfaces were prepared by a combination of practical wet processes on an alumin ium substrate: chemical etching, anodizing, and organic monolayer coating. Th e size of the larger pores formed by the chemical etching of aluminium is controlled by the concentration of HCl in the CuCl 2 /HCl etching solution. The etched aluminium is then anodized to introduce nanopores, followed by a pore-widening treatment that controls the nanopore size and porosity. The repellency for low-surface-tension liquids is enhanced by increasing the size of the larger pores as well as the porosity of the walls of the larger pores in this dual-pore morphology. Under optimized morphology with a fluoroalkyl-phosphate monolayer coating, an advancing contact angle close to 160º, a contact angle hysteresis of less than 5º and a sliding angle of 10º is achieved even for octane.

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Section: Surface Geometrymentioning

confidence: 99%

Fabrication of superoleophobic hierarchical surfaces for low-surface-tension liquids

et al. 2014

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“…electrolytic graining or electrograining is a process used for the creation of a uniformly pitted morphology on aluminium surfaces. Electrograining can increase the specific area of a smooth aluminium foil by up to a factor of 200 [Ono & Habazaki, 2011, Dyer & Alwitt 1981. The process is industrially applied in lithographic printing plates, where a larger surface area is necessary in order to enhance the water retentive properties of the aluminium and to improve the adhesion of the photosensitive coating which is deposited after electrograining and anodising of the aluminium substrate.…”

Section: Ac Electrograining Mechanismmentioning

confidence: 99%

“…1. Applied alternative AC current waveform during one period During the anodic half cycle oxidation of aluminium to Al +3 ions occurs; dissolved aluminium is removed to the bulk of the solution and cubic pits are formed [Dyer & Alwitt, 1981]. The reactions taking place during the positive polarisation are:…”

Section: Ac Electrograining Mechanismmentioning

confidence: 99%

“…The previously formed Al 3+ ions which were not yet removed from the surface, precipitate as aluminium hydroxide Al(OH) 3 (reaction 4). Aluminium hydroxide is insoluble in water and precipitates as a white gel [Vargel et al, (2004), Dyer & Alwitt, 1981]. The latter together with aluminium particles, water and ions from the electrolyte create an amorphous etch film, called smut layer, formed in a colloidal phase which masks the pits and causes an increase in the potential.…”

Section: Ac Electrograining Mechanismmentioning

confidence: 99%

“…The density and the number of pits are proportional to the electrolyte aggressiveness and the substrate conditions, whereas the pit size is related to the local anodic charge passed [Laevers et al, 1993, Terryn, 1988, Dyer & Alwitt, 1981, Dowell, 1979. The use of Hydrofluoric Acid leads to the formation of surfaces that are made of significantly smaller, shallower and more uniform pits with a much higher pit density as it is illustrated in Figure 4 [Wilson, 2006].…”

Section: Influence Of the Electrolyte On The Electrograining Processmentioning

confidence: 99%

See 2 more Smart Citations

Importance of Etch Film Formation During AC Controlled Pitting of Aluminium

Tzedaki¹,

Graeve²,

Kernig³

et al. 2012

Pitting Corrosion

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Rapid and Repeatable Self‐Healing Superoleophobic Porous Aluminum Surface Using Infiltrated Liquid Healing Agent

Nakayama

Koyama

Chen

et al. 2018

Adv Materials Inter

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This paper reports rapid self‐healing on superoleophobic hierarchically porous aluminum surfaces within 1 h even at room temperature. This self‐healing surface is prepared by infiltration of a liquid fluoroalkylsilane (FAS) coating into the substrate pores. The FAS‐infiltrated dual‐pore superoleophobic surface becomes superoleophilic after oxygen plasma treatment due to the damage done to the organic coating. However, the superoleophobicity is completely recovered by exposure to normal atmosphere at room temperature, and this rapid self‐healing is repeatable. The FAS liquid appears to coat the nanopore walls, rather than filling the nanopores. The high wettability of FAS on surfaces induces the rapid recoating of the plasma‐damaged surface, contributing to the self‐healing of the superoleophobicity.

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Surface Changes during A.C. Etching of Aluminum

Cited by 75 publications

References 2 publications

Fabrication of superoleophobic hierarchical surfaces for low-surface-tension liquids

Fabrication of superoleophobic hierarchical surfaces for low-surface-tension liquids

Importance of Etch Film Formation During AC Controlled Pitting of Aluminium

Rapid and Repeatable Self‐Healing Superoleophobic Porous Aluminum Surface Using Infiltrated Liquid Healing Agent

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