Growth of hydrophobic membrane on copper surface and study of its corrosive behavior

. Hydrophobic films were produced on a copper surface by chemical methods. The whole process consisted of three stages. Initially the hierarchical structure of the surface was achieved by in situ reduction of Ag + ions to Ag using silver nitrate solution, thereby creating a nanostructured surface. The copper surface was then coated with polydopamine by a simple immersion procedure. Finally, it was decorated with thiols, to achieve a hydrophobic surface. The wetting angle was used to evaluate the hydrophobicity of the produced surfaces. The anti-corrosion behavior of the produced hydrophobic films, were evaluated on the specimens that showed higher hydrophobicity by electrochemical methods. Electrochemical techniques (potentiodynamic polarization and resistance spectroscopy tests) were performed in 3.5% NaCl solution. Morphology was investigated by scanning electron microscopy (SEM). All experimental results showed a clear improvement in the corrosion behavior of the hydrophobic copper surfaces while the hydrophobicity was maintained after the corrosion tests.


Introduction
In recent years a plethora of metallic surfaces with special wetting ability have been manufactured through a combination of surface micro-and nanostructures and specific chemical composition, inspired by structures that exhibit materials of nature. Some of the mostly known water-repellent natural surfaces, are the lotus leaf, the shark skin and the skin of some insects. These metal surfaces with tailored wettability, are used in significant applications in corrosion protection systems, such as organic-water separation, fluid transport, self cleaning and anti-icing surfaces.
The wettability could be characterized by the contact angle (CA), between the surface and the droplet. When the CA of a surface is lower than 90•, the surface is described as a hydrophilic surface. When the CA is between 90• and 150•, the surface is described as a hydrophobic surface and for contact angles more than 150•, the surface is superhydrophobic. For rough surfaces, the wetting state can be described by the Wenzel and Cassie-Baxter models.
There are various coating methods to produce super-hydrophobic surfaces that can be categorized as: i) rough surface fabrication with low surface energy material and ii) rough surface modification with low surface energy material [1,2]. The most well-known methods for developing hydrophobic surfaces are sol-gel, electrospining, layer-by-layer, plasma spray coating. These methods, although widely used, have many disadvantages. Typical is the sol-gel method, which involves multiple and complex steps, the electrospinning method, which requires specialized equipment, consumes high amounts of energy and can be produced only one specific nanostructure (fibers). Special equipment is also required in the plasma spray method while the spin coating method is unfriendly due to the use of environmentally harmful solvents [3,4]. Another method which is widely used, in order to create hydrophobic surfaces, is the immersion method. In the literature, this method either involve multiple steps, or require long residence times in solutions, or even if they meet the criteria of the simple and short method, the coatings produced do not have satisfactory mechanical stability [5][6][7][8].
In this research work, hydrophobic films were developed on copper sheets used as substrate due to its excellent properties (low weight, electrical conductivity) by a simple immersion method and with short immersion durations in solutions. The hydrophobic surfaces produced showed very good resistance to aqueous corrosive sodium chloride (NaCl).

Experimental methodology
Copper sheets (20x20 mm) were used as substrate. Before coating, the substrates were mechanically polished down to 1200 grit size using abrasive SiC papers. The copper substrates were then ultrasonically cleaned in acetone solution for 30 min for degreasing, followed by oxide removal by immersion in 0.1 M HCl for 5 min and subsequently rinsing in water and ethanol. The cleaned substrates were immersed in the silver nitrate (AgNO3) solution (4 mM) for durations of 5, 10, 15, 20, 30, 40 and 50 minutes, in a temperature of 30°C while stirring at 300 rpm.
To achieve a coherent and uniform silver (Ag) coating, a polydopamine aqueous solution (PDA) was used. The production of polydopamine was as follows: dopamine (DOPA) (45Mm), was added to a Tris-buffer solution which was prepared by dissolving 10 mM trishydroxymethyl-aminomethane (C4H11NO3) in distilled water. The obtained pH of the solution was measured to pH=10. Samples were immersed for 20 min in the polydopamine aqueous solution, at a temperature of 40°C while the solution was constantly stirred at 300 rpm. Finally, for surface modification and reduction of surface energy, all specimens were immersed in an ethanolic solution of dodecanethiol (DDT) (0.1 M) for 1 hour.
The wetting characteristics of the sample surfaces were carried out by measuring static water contact angles. A water droplet of about 100 µl was used for each measurement.
The microstructure of the films developed, was examined by scanning electron microscopy (SEM). The corrosion behavior of the coated copper specimens that showed better hydrophobicity (at the initial characterization via contact angle measurement) was tested in 3.5% w/v NaCl aqueous solution by electrochemical techniques (potentiodynamic polarization and resistance spectroscopy (EIS) tests). Uncoated copper samples were also studied for reasons of comparison. All electrochemical experiments were performed in a three-electrode cell containing 3.5% w/v aqueous NaCl, according to ASTM D1193 IV. A platinum wire was used as an auxiliary electrode. The experimental installation of the electrochemical corrosion apparatus was in accordance with ASTM G 69-97 and ASTM G71-81. All electrochemical measurements were performed at room temperature (25°C). In the case of polarization, the potential scan rate was 0.1 mV/sec and the scan range was -800 to 600 mV relative to the reference electrode. Prior to the measurements of the polarization curves and the EIS, the working electrode was immersed in the test solution in open circuit (OCP) for 30 min to achieve steady state. The EIS was performed in the 0.01 Hz-100 kHz frequency range using peak-to-peak voltage of 10 mV.

Hydrophobicity and structural characterization
The contact angle between a water droplet of about 100 µl and the surface of the coated copper, with a thin layer of silver, for different immersion times in the silver nitrate solution (AgNO3) is shown in Figure1. Each value is an average of 10 measurements. The contact angle exhibits superhydrophobic behavior and maximum contact angle of 153° for a 15 min immersion time, in the silver nitrate solution. Figure 1b shows typical images of water droplets of about 100 µl on the surface of silver-coated copper corresponding to different times of growth of the silver films. For the initial testing of silver coating stability, the optimally coated samples (15 min) were immersed in an ultrasonic bath for various times and the probability of their hydrophobicity loss was investigated by measuring the contact angle as well as the possible abruption of the hydrophobic film. Figure 1c. shows that the contact angle decreases with increasing the immersion time in an ultrasonic bath. However, the hydrophobicity remains after 60 minutes and the contact angle remains almost constant at about 122°. It is noteworthy that no coating abruption was observed at any point on the coated specimens after 90 minutes in an ultrasonic bath. The results showed that there was a satisfactory stability and affinity of the developed silver films to the copper substrate.
The microstructure of the developed hydrophobic films is shown in Figure 2. A copper substrate in which the hydrophobic silver coatings were developed is also presented, for comparison. When the immersion time in the silver nitrate solution is 5 min, the coating shows discontinuities, as shown in the SEM image and the copper substrate. By increasing the immersion time to 10 min, the self-organization of silver ions and the development of needle-like nanostructures are observed. There are several clusters (of various sizes) so that the surface exhibits morphologically sufficient heterogeneity. Increasing the immersion time to 15 min, has as a result the breakdown of agglomerates and the creation of new structural morphologies. Needle-like morphologies are now scarce and the sample exhibits dendritic or leaf-like morphologies. In addition, a second morphology of spherical agglomerates of approximately 1 µm is shown. As the immersion time in the silver nitrate solution increases to 20 min, the leaf-like structures decay and larger clusterls of silver with polyhedral morphology are appeared. This morphology (polyhedral aggregates) remains for 30 min in silver nitrate solution. The homogeneity and uniformity of the coating are excellent for immersion times greater than 20 min. However, due to the polyhedral morphology and relatively large (but uniform) aggregates the hydrophobicity decreases with the contact angle ranging from 140-143 °. Figure 3 indicates that the character of the anodic and cathodic polarization curve for the silver-coated copper, is similar to that of the copper substrate, which indicates that the reactions, which occur in the two samples are the same. The same figure shows the values of corrosion potential and current. The hydrophobic silver layer, which was developed on the copper substrate, shifted the anodic and cathodic polarization curve to lower current densities, therefore increasing the corrosion resistance. It is worth noting that the hydrophobicity of the samples was maintained at a contact angle of 142 °. Figure 4 shows the Nyquist and Bode diagrams from EIS measurements. As observed, the copper substrate had a value of /Z/ = 6 ohm cm 2 , at a high frequency of 10 4 Hz. However, the coated copper showed a value of /Z/ = 21 ohm cm 2 which is almost 4 times higher than that of the substrate, on the same frequency. Similarly, at the low frequency of 0.01 Hz, the /Z/ value of the copper substrate is 1.4 kohm cm 2 , while that of the coated copper is 7 kohm cm2. The high value of the composite impedance /Z/ of the hydrophobic coating, compared to that of the copper substrate, indicates that the developed hydrophobic films are more corrosion resistant. The Nyquist diagrams show higher ohmic and capacitive resistance (real and imaginary part respectively) for the hydrophobic silver film.

Conclusions
Hydrophobic coatings were grown on a copper surface by chemical methods. The whole methodology is fast and simple, non-time-consuming and low-cost. By adjusting the immersion time in the silver nitrate solution, silver films of varying morphologies were studied which were studied for their hydrophobicity. Optimum contact angle at 152.6 ° was achieved for a dip time of 15min. In this case the uniformity of the coating topology was achieved while its morphology reveals feather-like nanostructures. Developed hydrophobic silver film improves the corrosion resistance of copper thus demonstrating the multifunctionality of the developed nanostructured films.