Electrodeposited Zn-Ni-sisal Nanocrystals Composite Coatings - Morphology, Structure and Corrosion Resistance

Zn-Ni alloys have been used to decrease the corrosion rate of carbon steel substrates. These are used in applications such as bolt coatings, threaded parts, swift valves for gas pipelines, aircraft landing gear, brake system components and others. Zn-Ni coatings containing nanocrystals of cellulose (CNC) obtained from sisal fiber (Sif), a natural polymer, were manufactured using the electroplating technique. Obtaining the nanocrystals involved bleaching raw sisal fiber and then acid hydrolysis to extract the nanocrystal. The effect of the concentrations of the CNC-Sif (0% v/v, 2%v/v, 3%v/v, and 4%v/v) on the morphology and microstructure of the Zn-Ni coating was analyzed through Scanning Electron Microscopy (SEM), X-ray diffraction, and roughness measurements using confocal microscopy. The effect of the addition of CNC-Sif on the efficiency of galvanostatic deposition was analyzed. The corrosion rate through mass loss and electrochemical tests were also analyzed. The effect of adding CNC-SIF on coating microhardness investigated. This study show that the addition of nanocrystals alters the structure, the morphology, increases current efficiency and the corrosion resistance of the Zn-Ni coating and these effects are more significant with the addition of 2% v/v. The results obtained indicate that the addition of the CNC-Sif in the Zn-Ni coating is promising, because it reduces the energy consumed during the electrodeposition process in addition to increasing corrosion resistance of the Zn-Ni and the microhardness.


Introduction
Zinc coatings obtained through electroplating are widely used to protect the substrate against corrosion due to the barrier effect and cathodic protection.However, in highly corrosive environments like marine or polluted atmospheres, the corrosion rate of zinc is considerable, imposing significant constraints on the applicability of zinc coatings.Furthermore, in these media, the corrosion rate of zinc is much higher than that of the steel substrate 1 .Therefore, it is possible to increase the useful life of the zinc coating and maintain its ability to cathodically protect the steel substrate.Apart from the inclusion of organic additives, there exist several possibilities to enhance the corrosion resistance of zinc coatings include imparting superhydrophobic properties to the metal surface, incorporating nanoparticles, and introducing Ni or Fe into the coating.The corrosion resistance of zinc coating is also affected by the electroplating method.It has been found 2 that pulse reverse curent (PRC) results in a zinc deposit with corrosion resistance superior to that of the coating obtained through direct current and pulsed current.This effect is attributed to obtaining a compact corrosion product beyond the structure of the PRC deposit.
It has been found 3 that the superhydrophobic properties of zinc coating can be obtained by subjecting the coating to an ultrasonic treatment with stearic acid.This procedure is done after electrodeposition from sulfate-acetate solution.The introduction of superhydrophobic properties resulted in an increase in the corrosion resistance of the zinc coating in 0.5 M NaCl which is attributed to a gas interlayer on coating surface in aqueous solutions.
Electrodeposited nanocomposites consisting of a metallic coating with ceramic nanoparticles for use as a protective coating on steel substrates have been widely studied in recent years.It has been found that the corrosion resistance of zinc coating improves with the addition of various nanoparticles such as graphene oxide (GO) 4 , SiC 5 , TiO2 6 , Al2O3 7 , and cellulose nanocrystals (CNC) obtained from soybean hulls 8 and cotton fibers 9 .This effect is mainly related to the increased compactness of the deposit and the occurrence of a physical barrier caused by the presence of nanoparticles.
Regarding the addition of Fe, it has been found 10 that the corrosion resistance of zinc coating in NaCl solution increases with the presence of 14wt% of Fe.This effect is related to the presence of the Γ1-Fe5Zn21 phase.Materials Research However, Zn-Ni coatings are the main Zn-based alloys from electroplating.These coatings are used in applications such as bolt coatings, threaded parts 11 , swift valves for gas pipelines, aircraft landing gear, and auto parts including fuel transport lines and brake system components.The addition of nanoparticles to Zn-Ni alloys enhances their corrosion resistance and improves the cost/benefit ratio of the material as it reduces the amount of costly Ni needed to provide adequate corrosion resistance.It has been found that the corrosion resistance of a Zn-Ni coating increases with the addition of ceramic nanoparticles such as WC 12  In the galvanostatic electrodeposition process, the current efficiency is important from a practical point of view, since a higher deposition efficiency implies a lower energy consumption.However, there is little information in the literature about the effect of adding ceramic nanoparticles on the current efficiency of Zn-Ni coating.Roventi et al. 18 found that the addition of ZrO 2 and Al2O 3 in the alkaline bath at concentrations of 5 g/L and 10 g/L does not result in a significant change in the current efficiency of a Zn-Ni coating, and the results are within the margin of error.However, in the deposition of Zn from an alkaline bath it was found 19 that the addition of SiC nanoparticles decreases the current efficiency.This effect is attributed to the change in the reduction potential of hydrogen ions, resulting in an increase in the H 2 partial current, which causes a decrease in the current efficiency.These results therefore show that the effect of ceramic nanoparticles on current efficiency depends on the nature of the nanoparticles.
The superior corrosion resistance of a Zn-Ni coating resulting from the incorporation of ceramic nanoparticles in the coating is attributed to the filling of defects by the nanoparticles, making the alloy matrix more uniform 13,14 , and to the decrease in the active surface in contact with the corrosive medium 15 .Apart from the addition of ceramic nanoparticles, other materials of nanometric dimensions may fill defects in the alloy matrix, and being electrically neutral and stable in the corrosive solution, they may also promote an increase in the corrosion resistance of the coating.Among such materials cellulose nanocrystals (CNC) stand out.These materials are obtained from various natural sources and the fibers undergo a process that involves the removal of the amorphous structure, usually through acid hydrolysis [20][21][22] .
Cellulose nanocrystals have the advantage of coming from renewable and low-cost products, and as well as being environmentally friendly, they are easy to process and have low density.In addition, they exhibit a favorable mechanical behavior, high hydrophilicity and lipophilicity, and great emulsification stability.These characteristics make the use of CNC promising for a wide range of applications that include biomedical and pharmaceutical applications, such as their use in delivery vehicles for anticancer agents and their use as a reinforcement phase of polymer matrices 23,24 .However, there is little information about the effect of these nanocrystals on metallic coatings obtained by electrodeposition.To the best of our knowledge, studies on this effect are limited to those on the addition of CNC obtained from cotton fiber 9 and soybean hulls 8 .These studies show that the addition of such CNC decreases the corrosion rate of the coating and this effect is mainly related to the decrease in the roughness of the coating due to the penetration of nanocrystals into the surface defects of the coating.The decrease in the corrosion rate is also related to the CNC acting as an inert barrier resulting in a decrease in the active surface area of the coating.
Various cellulosic materials can be used to obtain CNC, such as sisal fiber, cotton fiber, soy husks, wood pulp, jute, hemp and flax [25][26][27][28][29] .Due to its high cellulose content (50% to 74%), sisal fiber, which is obtained by defibrillation through the sisal leaf, is a promising source of CNC 30 .Furthermore, sisal is the main hard fiber produced in the world, and it is an agricultural product of great socioeconomic importance in several producing countries such as Brazil 31 .It is also important therefore to carry out studies on new applications of sisal fiber in order to add value to this product.
Studies on CNC obtained from sisal fiber (CNC-SiF) mainly involve the effect of the incorporation of these nanocrystals as a reinforcement phase of a polymer matrix.These studies show that the incorporation of CNC-SiF into a polymer matrix can improve the mechanical strength and toughness of the composite, however, this effect depends on the type of polymer matrix used.It was found 32 that the incorporation of CNC-SiF, at levels of 5 and 10 wt%, results in a 100% increase in the modulus of the matrix consisting of waterborne polyurethane (WBPU), and that the elongations are maintained at around 65%.On the other hand, it was found 28 that the incorporation of CNC-SiF at 3 wt% in the polypropylene matrix increases the tensile strength and the modulus around 4.40% and 7.16%, respectively, while the impact strength increases by 21.96 J/m 2 to 24.2 J/m 2 .However, there are no published references on the effect of the addition of CNC-SiF on the characteristics of metallic coatings.
In addition to being inert nanocrystals obtained from a renewable natural product and relatively low cost, it is interesting to investigate the effect of adding CNS-SiF to a metallic electrodeposit.Thus, in the present work, a comparative analysis was made to investigate the effect of adding cellulose nanocrystals obtained from sisal fiber on the morphology, microstructure, and deposition efficiency of a Zn-Ni coating.The effect of the addition of these nanocrystals on the coating corrosion resistance is also investigated.

Production and characteristics of the nanocrystal of sisal fiber
Obtaining the nanocrystals of sisal fiber (CNC-Sif) involved bleaching raw sisal fiber and then subjecting it to acid hydrolysis to extract the nanocrystal 33 .
In the first stage of bleaching, around 10.0 g of the ground and sieved fiber (16 mesh) was put into a beaker containing 200 mL of sodium hydroxide solution (5% NaOH, w/v) at a temperature of 90 °C.The system remained under constant agitation for 90 min.After cooling, filtration was carried out under a vacuum.The retained solid material was washed with distilled water until a neutral pH was reached.The fiber was dried in an oven with air circulation at 50 °C until it reached a constant weight.
In the second stage of bleaching, the fiber was put into a mixture of sodium hydroxide solution (NaOH, 5% w/v), glacial acetic acid PA (CH 3 COOH, 5% v/v), and sodium hypochlorite (NaClO, 2 and 5% (v/v), at a temperature of 80 °C).The system remained under constant agitation (600 rpm) for 120 min.After cooling, filtration was carried out under vacuum, washing the material with distilled water until reaching a pH 7. The fiber was dried in an oven with air circulation at 50 °C until a constant weight was reached.This bleaching step was repeated three times.
To extract sisal cellulose nanocrystals, the bleached fibers (5.0 g) were subjected to acid hydrolysis in a sulfuric acid solution (100 mL H 2 SO 4 56% v/v) under vigorous stirring at 60°C for 30 min.The resulting suspensions underwent 11 centrifuges of 10 min and 3400 rpm.After this step, the solution was resuspended in 500 mL of distilled water and dialyzed in water to remove excess acid (pH between 6 and 7).After neutralization, the solution was ready for use in the electrolytic bath.The characteristics of the nanocrystals are listed in Table 1.Zeta potential was determined at 25 °C using a Malvern Nano-ZS apparatus.Three measurements were performed.The dimensions of the nanocrystals were obtained using transmission electron microscopy (TEM, Tecnai™ G2 F20) with the help of Image J software and 50 measurements were computed 33 .Measurements show that the sisal nanocrystals exhibit a whiskers shape with nanometric dimensions.
The results reported in Table 1 show that nanocrystals have a potential Zeta value of less than -30 mV, generally considered the limit between uncharged and charged particles 34 .

Bath deposition and electrodeposition process
Zn-Ni coating was obtained from an acid bath (pH = 3.5, the composition of which is detailed in Table 2 35 .
Initially, coatings were obtained in the absence and presence of the following concentrations of CNC-Sif added to the deposition bath: 1% v/v, 2% v/v; 3%v/v; and 4% v/v.For a CNC-Sif concentration of 5% v/v, the adhesion of the coating to the substrate was not adequate.On the other hand, the addition of 1% v/v of the CNC-Sif was not enough to change the corrosion rate of the Zn-Ni coating obtained through mass loss therefore the effect of the addition of this concentration was not analyzed in the other tests.
The coating was deposited at room temperature without agitation, using AISI 1020 carbon steel as substrate.The depositions were carried out at a current density of 10 mA/cm 2 applied for 18.5 min, resulting in a coating with a thickness of 5 μm.As a counter electrode (anode) a 5 mm diameter graphite bar was used.
Table 3 lists the pH and electrical conductivity values at 25° C for the deposition bath in the absence and presence of different concentrations of the CNC-Sif.

Analysis of morphology and structure
A scanning electron microscope (SEM, model Quanta 400 FEI) equipped with an energy dispersive spectrometer (EDS) detector was used to analyze the morphology and composition of the Zn-Ni coatings.The topographic images and the surface roughness of the coating were obtained by laser scanning confocal microscopy (LSCM) using the Olympus model LEXT OLS4100 equipment.The roughness parameters considered were: Sa (arithmetic mean of the absolute value of the surface departure above and below the mean plane within the sampling area, this parameter is used generally to evaluate surface roughness), Sp (height of the highest peak within the defined area), and Sv (depth of deepest valley within the defined area).
The parameter S a was determined through the following Equation 1 36 : where: A represents the defined scanning (or observation) area, and x, y, z correspond to the coordinates of length, width, and height, respectively.
The coating structure was determined by X-ray diffraction (XRD) analysis, using a Bruker D8 Advance ECO, with Cu-Kα-1 radiation (1.54 Å / 8.047 keV).From the XRD diffractograms, the relative texture coefficient (T C ), the size of the crystallites, and the microstrain of the Zn-Ni coating were determined.
The texture coefficient (Tc) was obtained using the following Equation 237 : where: I (hkl) is the peak intensity of Zn-Ni coating, I 0(hkl) is the intensity of peaks of standard Zn-Ni powder sample, taken from JCPDS file card number 47-1019, and n is the number of peaks present in the diffractogram.
The Debye-Scherrer Equation 3 was used to calculate the average crystallite size of the coating from the peak width at the half maximum of the crystal peaks 15 .
( ) where: d is the crystallite size; is the wavelength of the element used for the diffraction, is the peak width at the half maximum of the crystal peaks; and θ is the corresponding angle.
The microstrain was obtained using Equation 438 cos / 4 hkl ε β θ = (4)   where: ε is the microstrain, is the full width at half maximum, and is the diffraction angle.

Deposition efficiency
Deposition efficiency of the galvanostatic deposition was evaluated through the current efficiency (% CE) using the following Equation 5: where: mr is the mass of the Zn-Ni coating, and mc is the theoretical mass calculated using Equation 639 : . . . .
where: t i is the deposition time (second), M i is the atomic mass of that element (g.mol -1 ), i is the current of deposition (ampers), Ci is the weight fraction of metal, n i is the number of electrons transferred and F is Faraday's constant.
The m c can be related with the thickness of the coating following (Faraday's law) Equation 7: where: t is the coating thickness, (µm); d Zn is the Zn-Ni coating density (g⋅cm −3 ); S is the electrodeposition surface (cm 2 ).

Corrosion resistance
The effect of the addition of the CNC-Sif on the Zn-Ni coating corrosion resistance was evaluated in a 0.5 mol/L NaCl solution through mass loss measurements and electrochemical tests.Measurements were made at room temperature, around 25 °C, and all values were obtained in triplicate.The samples were immersed for 24 hours in the corrosive solution.
The cleaning of the surface of the Zn-Ni coating after immersion in an NaCl solution was performed with a solution of glycine (aminoacetic acid -C 2 H 5 O 2 N) 1.36 mol/L at room temperature.The corrosion rate (CR) in mm per year was obtained from mass loss measurements, Equation 840 : where: K is a constant (for CR mm/year, K = 8.76 x 10 4 ); W is the mass loss (g); A is the exposed area (cm 2 ); t is the immersion time; (h) D is the density of the coating.The electrochemical measurements, namely the potentiodynamic polarization and electrochemical impedance spectroscopy (EIS), were performed in a three-electrode cell using a saturated calomel electrode (SCE) as the reference electrode, and graphite as the counter electrode.These measurements were obtained with an AUTOLAB Potentiostatic & Galvanostatic model PGSTAT 100 instrument, using Autolab software NOVA 1.7.The potentiodynamic polarization curves were obtained at a scan rate of 10 mV.s -1 in the anodic direction.The polarization resistance (Rp) values were obtained next to the corrosion potential (overpotential of 10 mV) from the inverse of the slope of a plot of the potential versus the current density.The samples were immersed in the corrosive solution for 3 min before being polarized.
The EIS measurements were performed at the corrosion potential over a frequency range of 100 kHz to 10 mHz, using a 10 mV amplitude of the sinusoidal voltage.

Microhardness
The Vickers microhardness measurements of coating were performed em um microdurometer (Model Shimazdu microdurometer -HMV series), carried out with a load of 100 g and time of load of 15 s.Measurements were made in triplicate.

Effect of the addition of CNC-Sif on the composition, morphology and structure of the Zn-Ni coating
Table 4 shows the effect of the CNC-Sif concentration in the bath on the Ni percentage in the coating.With the addition of 2% v/v, the Ni content in the coatings increases (from 8.7 wt.% to 9.5 wt.%).However, the effect of the nanocrystal concentration on the Ni content of coating shows no clear trend.Furthermore, the Ni content values obtained are within the margin of error.
Regarding the effect of ceramic particles on the composition of the Zn-Ni coating, this effect depends on the pH of the bath and on the type and concentration of the particles.Electrodeposited Zn-Ni-sisal Nanocrystals Composite Coatings -Morphology, Structure and Corrosion Resistance In alkaline deposition baths, it has been found that the addition of nanoparticles of ZrO 2 , Al 2 O 3 , and SiC 18 , as well as the addition of SiC micro-particles 41 does not affect the Ni percentage in the coating.A similar effect has been found in acid deposition baths regarding the addition of Al 2 O 3 nanoparticles 42,43 .However, with the increase in the concentration of Al 2 O 3 nanoparticles from 6 ml/L to 20 ml/L, there is a decrease in the Ni content in the coating.This effect was also observed 43 with the addition of SiC nanoparticles in the acid deposition bath, which resulted in a decrease in Ni concentration.The decrease in the concentration of Ni content with the addition of SiC nanoparticles is related to the increase in the hydrogen evolution reaction, HER, which results in the formation of the surface film of Zn(OH) 2 , which can inhibit the reduction of cations of Ni 43 .Based on the effect of the addition of nanocrystals on current efficiency, as will be seen in Section 3.3, it is not possible to state that the presence of nanocrystals caused an increase in HER in the present work.
Figure 1 shows the SEM images of the surface of the Zn-Ni coatings obtained from bath deposition without and with varying contents of CNC-Sif.In Figure 1 it can be seen that the coatings exhibit the characteristic nodular like morphology that is similar to the Zn-Ni coating obtained at 10 mA/cm 2 by Roventi et al. 18 .The effect of the addition of the CNC-Sif on the compactness of the coating is not noticeable, however, a greater agglomeration of the grains in the coatings obtained in the presence of 3%v/v and 4%v/v compared to the coating obtained in the presence of 2%v/v can be seen.
To analyze the effect of the CNC-Sif on the morphology more clearly, the coatings were analyzed using a confocal microscope to obtain images and observe roughness.Table 5 lists the roughness values of the Zn-Ni coatings in the absence and presence of different levels of the CNC-Sif.These results show that the addition of the nanocrystals reduces the roughness of the coating, and the lowest roughness value corresponds to the coating obtained in the presence of 2%v/v of the CNC-Sif.
The two-dimensional topographical images of the Zn-Ni coatings are shown in Figure 2.These images show that the coatings exhibit a sand dune-type morphology and that the addition of the nanocrystals changes the smoothness of the coating surface.With the addition of the nanocrystals, the width and height of the sand dune increase, and the coating surface becomes smoother and consequently less rough.This effect is more significant with the addition of 2% v/v of nanocrystals, indicating that there is an optimal concentration of nanocrystals at which the roughness is minimal.
It has been reported [44][45][46] that the effect of adding ceramic nanoparticles generally increases the roughness of metallic coatings obtained by electrodeposition.However, this effect depends on the amount and type of nanoparticle added, in addition to the coating composition.The addition of a small amount of graphene oxide (GO) nanoparticles decreases the roughness of the Ni coating obtained by electrodeposition but from the addition of 0.02 wt%, the roughness increases.It has also been found that the addition of SiC nanoparticles (20 g/L) 45 and of TiO 2 -CeO 2 ceramic particles (2.5, 5, and 7.5 g/L) 46 increases the roughness of the Ni-P coating.
The effect of the addition of nanoparticles on the coating roughness is related to the introduction of defects due to the presence of the nanoparticles, the performance of the nanoparticle as a heterogeneous nucleation site, and the effect of the nanoparticle in inhibiting the diffusion of metallic cations in the solution during the electrodeposition process.
It is suggested that the presence of the nanoparticle introduces defects such as pores, making the coating less uniform.By acting as a nucleation site, the nanoparticles cause surface perturbation, which becomes more intense throughout the process, resulting in an increase in roughness.However, this effect depends on the distance between the nanoparticles, and the smaller the distance between them leads to a smoother deposit and, consequently, less roughness 45 .During the electrodeposition process, the presence of nanoparticles can inhibit the diffusion of metallic cations, thus limiting the free path for diffusion.This leads to the selective diffusion path of the metallic ion, resulting in the selective growth of the deposit and consequently the increase in roughness 44 .
The factors that affect the roughness of the coating containing the nanoparticles depend on the level of agglomeration of the nanoparticles as a greater agglomeration favors the roughness of the coating.The increase in the agglomeration of nanoparticles results in a greater distance between the nucleation sites, which favors vertical growth to the detriment of horizontal growth, resulting in a more intense surface landscape and consequently greater roughness.A greater agglomeration of nanoparticles favors the diffusion hinderance of metallic cations and consequently the selective diffusion path of metallic ions.Furthermore, a greater agglomeration of nanoparticles may favor the occurrence of defects 44 .
The decrease in the roughness of the Zn-Ni coating with the addition of the sisal fiber nanocrystals found in the present work indicates that the distribution of the nanocrystals was sufficiently homogeneous to avoid a more intense agglomeration that could increase the roughness.It is possible that the decrease in roughness caused by the addition of these nanocrystals is related to their performance as nucleation sites.With a sufficiently small distance between them this enables the formation of a less intense surface landscape and consequently a less rough surface.It is also possible that the nanocrystals, due to their small size, can fill the local defects (flaws, gaps, grooves) on the coating surface, making it less rough.
The increase in roughness with an increasing content of CNC-Sif beyond 2%v/v can be attributed to a greater agglomeration of nanocrystals.Although this agglomeration was not enough to increase the roughness in relation to the coating without the nanocrystals, it may have been enough to increase the distance between the crystals that act as nucleation sites and favor the selective diffusion path of the metallic ions.
Figure 3 shows the X-ray diffractogram pattern of the Zn-Ni coating obtained in the absence and presence of different concentrations of CNC-Sif.In this figure, the presence of fine diffraction peaks is observed, which is characteristic of the crystalline structure.In the diffractograms, the presence of the following phases is observed: the η phase, which corresponds to a solid solution of Ni in Zn (JCPDS card number 87-0712); the γ phase, which corresponds to a Ni 5 Zn 21 intermetallic compound (JCPDS card number 06-653); and the α phase, which corresponds to a solid solution of Zn in Ni (JCPDS card number 87-0713).The presence of Fe, peak (200), can also be observed and this occurs due to cracks in the coating, which results in the exposure of the steel substrate.The presence of phases in the Zn-Ni coating depends on the coating composition and deposition conditions.The η and γ phases are found in coatings with nickel contents from 5.0 to 14.0 wt.% obtained from an acid chloride bath 47 , therefore, in a composition range which includes the coatings analyzed in the present work.
To investigate the effect of the addition of CNC-Sif on the crystallographic orientation of the Zn-Ni coating, the texture coefficient (Figure 4) was calculated for each peak of diffraction patterns.A higher texture coefficient, TC, for a given plane, indicates that the greater will be the preferred orientation of this plane in the coating.Figure 4 shows that the addition of 2.0% v/v and 3.0% v/v raises the TC corresponding to the γ(330) plane, and this effect is more significant with the addition of 2.0% v/v.In the Zn-Ni coating, the (330) plane, which corresponds to γ-Ni 2 Zn 11 phase 48 , is more closely packed, thus the increase in the TC of the coatings content 2.0% v/v and 3.0% v/v leads to an increase in the coating packing density thus favoring increased corrosion resistance 15,48 .However, with the addition of 4%v/v, the TC corresponding to the (330) plane decreases in relation to the absence of CNC-Sif, while increasing the TC corresponding to (101) plane.
The crystallographic orientation of the Zn-Ni coating depends on the Ni content in the coating, so the increase in Ni content favors the crystallographic orientation in the (330) plane belonging to the γ phase 48 .However, the addition of CNC-Sif does not significantly affect the Ni content in the coating (Table 4).Furthermore, the coating obtained with the addition of 4%v/v of CNC-Sif has a TC for the plane (330) that is lower than that of the other coatings, although it has a higher Ni content than the other coatings, except for the coating obtained in the presence of 2%v/v.
The increase in intensity of the γ phase with (330) plane orientation in an Zn-Ni coating due to the addition of nanometer-sized particles has also been observed with the incorporation of ceramic nanoparticles such as Al 2 O 3 15 and TiO 2 48 .However, it is unclear how this effect occurs.It is possible that the effect of the addition of the CNC-Sif in the presence of the crystallographic planes is related to the fact that the nanocrystals act as a heterogeneous nucleation site.The growth of the metallic deposit during the deposition process tends to occur preferentially in the planes with lower free energy 49 , and the nucleation from the nanocrystals favored the growth of the deposit in the plane (330).However, in the coating obtained with the addition of 4%v/v of nanocrystals, a greater agglomeration of the  From the X-Ray diffraction patterns (Figure 3), the sizes of the crystallites, considering the average of the three highest intensity peaks, and the microstrain present in the Zn-Ni obtained in the absence and in the presence of the nanocrystals were determined.These results, which are listed in Table 6, show that the effect of the addition of these nanocrystals on the crystallite size depends on the concentration of the crystallite added in the deposition bath.The addition of 2% v/v and 3% v/v of CNC-Sif results in a reduction in the size of the crystallites.However, the addition of 4% v/v causes the crystallites to increase in size.
Depending on the amount and type of nanoparticles, the incorporation of ceramic nanoparticles in the Zn-Ni coating can cause either a decrease or an increase in the size of the crystallites.It has been found that with the incorporation of Al , and WC 51 , the nanoparticles reduce the size of the Zn-Ni coating crystallites.However, Roventi et al. 18 found that the incorporation of ZnO 2 and Al 2 O 3 nanoparticles increases the crystallite size, while the addition of SiC nanoparticles does not appreciably affect the crystallite size.
The decrease in crystallite size caused by the addition of the nanoparticles is related to the role of the nanoparticle as a site of heterogenous nucleation, and to the effect of the nanoparticle on the atomic diffusion during the deposition process.With the increase in the number of nucleation sites, and consequently in the nucleation rate, there is a decrease in the distance between them, which restricts the growth of crystallites, thus resulting in their refining 50,51 .On the other hand, the presence of nanoparticles inhibits the surface diffusion of atoms toward growing centers, which inhibits crystallite growth 52 .It has also been suggested that the nanoparticle acts as a protuberance at the metallic layer/ substrate interface, which results in an increase in current density and nucleation rate 51 .
The fact that ceramic nanoparticles as well as the sisal nanocrystals analyzed in the present work have a contradictory effect on refining the crystallites is probably related to the distribution of these particles during the deposition process.A more uniform distribution of nanocrystals results in a smaller distance between them, and therefore between the nucleation sites, which favors the refining of crystallites.However, from a certain concentration of nanocrystals, the level of agglomeration of the nanocrystals increases with increasing concentration, resulting in a greater distance between them, which has a less effective effect on inhibiting the size of the crystallites.This behavior may be related to the lower crystallite refining caused by the presence of 3%v/v of CNC-Sif in relation to the addition of 2%v/v.
A higher concentration of nanocrystals, as observed with the addition of 4%v/v, probably resulted in a level of agglomeration of the nanocrystals that caused a distance between them that did not allow the refining of crystallites to occur, despite favoring their growth.
In relation to microstrain, the results in Table 6 show that this parameter has an inverse behavior in relation to the size of the crystallites, with an increase in the microstrain as the grain size decreases.A similar behavior was found with the incorporation of silica nanoparticles and Mesoporous-silica (MPS) in the Zn coating 53 , with the incorporation of a carbon nanotube in the Ni coating 54 , and with the incorporation of Y 2 O 3 nanoparticles in the Ni-W coating 55 .
The increase in the microstrain of the metallic coating with the incorporation of the nanoparticle is related to the inconsistency between the nanoparticle and the metallic matrix 54 .The addition of 2%v/v and 3%v/v of CNC-Sif promotes a mismatch between the nanocrystals and the Zn-Ni matrix, which causes tension between these phases and consequently increases the microstrain.As with the size of the crystallites, the presence of the nanocrystals in the microstrain is also related to the distribution of the nanocrystal coating.With the increase in the content of the nanocrystals from a certain value, the agglomeration of nanocrystals is favored, which reduces the amount of nanocrystals per volume to a level that leads to a decrease in the level of strain introduced by them.This behavior is related to the decrease in microstrain from the addition of 2% v/v of nanocrystals.This has also been observed with the incorporation of carbon nanotubes in the Ni coating 54 and Y 2 O 3 nanoparticles in the Ni-W coating 55 The increase in microstrain can cause cracking in the coating, resulting in the deterioration of the corrosion resistance 56 .However, the SEM photomicrographs (Figure 1) show that the increase in microstrain of the coating in the coatings containing 2% v/v and 3% v/v CNC-Sif was not sufficient to cause cracking in these samples.

Current efficiency
Figure 5 shows the effect of adding CNC-Sif on the current efficiency of a Zn-Ni coating.The results indicate that the addition of 2% v/v of the nanocrystals in the deposition bath increases the deposition efficiency of the Zn-Ni coating.However, as the nanocrystal content increases from this concentration, the current efficiency tends to decrease, and it is observed that the values corresponding to the addition of 4% v/v is within the margin of error of the current efficiency corresponding to the absence of these nanocrystals.
Some studies have found an increase in the current efficiency of metallic coatings with the addition of ceramic nanoparticles such as Al 2 O 3 in Cr 57 , SiC in Ni 58 , and ZnO in Ni 59 .To explain the increase in current efficiency due to the addition of ceramic nanoparticles, it has been proposed 49 that the transport of metallic ions towards the cathode surface is facilitated by the formation of a film of these ions around the nanoparticles, which makes reduction faster.
The effect of the addition of an additive on the deposition efficiency of metallic coatings is often related to viscosity and hydrogen evolution.With the increase in the viscosity of the deposition bath, the mass transport of metallic cations to the cathode/solution interface is inhibited, resulting in a decrease in the deposition current of metallic cations and, consequently, in the current efficiency 60 .However, as can be seen from Table 3, the addition of CNC-Sif to the deposition bath increases the conductivity of the bath, which indicates that the viscosity is not altered by the presence of the nanocrystals.The increase in hydrogen evolution, as this is a concurrent reaction of the reduction reaction of metallic cations, tends to decrease the deposition efficiency.However, the results indicate that the addition of the nanocrystals does not cause a sufficient increase in hydrogen evolution to decrease the current efficiency.
It is possible that the effect of the addition of CNC-SiF on the current efficiency is related to the morphology of the coating.The hydrogen evolution reaction and consequently the decrease in current efficiency is favored by the presence of defects on the coating surface, as the defects act as hydrogen adsorption sites 61 .As seen in Table 5, the addition of CNC-Sif, mainly at 2% v/v, reduces the roughness of the coating, which indicates a more compact surface with fewer defects, which can result in less hydrogen evolution, and consequently higher current efficiency.The decrease in roughness with increasing nanocrystal content from 2% v/v may be related to the increase in current efficiency due to this content.It is also possible that the increase in current efficiency is related to the performance of the nanocrystal as a heterogeneous nucleation site.As seen in item 3.1, the decrease in crystallite size caused by the addition of the nanocrystals indicates the role of the nanocrystals as nucleation sites.The decrease in current efficiency from the 2% v/v content may also be related to the increase in the agglomeration level of the nanocrystals, which results in a decrease in the number of nucleation sites.

Effect of the addition of sisal nanocrystals on the corrosion resistance of the Zn-Ni coating
The effect of the addition of the CNC-Sif on the corrosion resistance of Zn-Ni coating was investigated through mass loss tests and electrochemical tests.These tests include obtaining the corrosion potential, E corr , and the polarization resistance, R p , through the potentiodynamic polarization curve, and electrochemical impedance tests.
Figure 6 shows the values of the corrosion rate obtained from the mass loss tests carried out after 24 hours of sample immersion in 0.5 M NaCl solution.The results show that the addition of the nanocrystals up to a content of 3%v/v decreases the corrosion rate of the coating, and this is lower for a content of 2%v/v.The addition of 1% v/v of CNC-Sif does not significantly change the corrosion rate of the coating.
The potentiodynamic polarization curves, Tafel curves, of the coating obtained in the absence and presence of varying levels of CNC-Sif contents are represented in Figure 7.The corrosion potentials, E cor , obtained from these curves are listed in Table 7.These results show that samples containing nanocrystals have a higher E cor , which indicates that they tend to present a higher corrosion resistance, and this is higher for the coating obtained in the presence of 2% v/v of CNC-Sif.However, a higher E cor does not necessarily indicate a lower corrosion rate.An important limitation of using E cor to evaluate the corrosion resistance is that the effect of the presence of the corrosion product on the corrosion rate is not taken into consideration 62 .
Figure 7 shows that in the anodic region from the potential around -0.4 V vs ECS the current density presents a small variation, indicating behavior passivation.This is also observed in the Zn potentiodynamic polarization curve in the 0.5 M NaCl solution 63 .The curve corresponding to the addition of 2% v/v of CNC-Sif displays the lower current density in this region compared to the other curves.This indicates a greater protective capacity of the passive film of the coating containing this concentration of nanocrystals, which should favor the corrosion resistance of this deposit in relation to the others.However, it is not possible to clearly distinguish the current density in the passive film forming region.This difficulty in distinguishing the corrosion resistance of coatings using qualitative analysis of the potentiodynamic polarization curves was also observed in the results obtained by Close et al. 63 .These authors investigated the effect of the addition of the additive (Hydroxybenzaldehyde (4-HB) and Ammonium Thiocyanate (NH4SCN)) on the corrosion resistance of a Zn-Mn coating in NaCl solution, by linear polarization resistance.Their results indicate that although the addition of the additive decreases the corrosion rate of the coating, it is not possible to distinguish the potentiodynamic polarization curves of these coatings in the anodic region.
It is possible that the addition of 2% v/v of CNC-Sif acted as a support for the formation of corrosion products that act as a passive film, thus favoring the formation of these products.However, this effect is not clear in relation to the other concentrations analyzed.It has been found that ceramic nanoparticles such as Si2O2 act as a support for the formation of zinc hydroxide chloride (Zn5(OH)8Cl2H2O) which acts as a passive film favoring an increase in the corrosion resistance of Zn coating in an NaCl solution.However, for the formation of zinc hydroxide chloride, the coating should remain immersed in the solution for a minimum time 64 .
In a future work, the effect of CNC-Sif on the formation of corrosion products in the Zn-Ni coating will be investigated using XPS and X-Ray diffraction after the coating has remained immersed in the NaCl solution for different periods.Furthermore, there are plans to investigate how this affects the corrosion rate of the coating.
Figure 8 shows the values of polarization resistance, R p , obtained from the potentiodynamic polarization curves of potential vs current density.Considering that a higher value of R p indicates a greater resistance to corrosion, Figure 8 shows that the addition of the CNC-Sif decreases the corrosion rate of the coating, with the sample containing 2%v/v of nanocrystals performing the best.
The results from electrochemical impedance (EIS) are shown in Figure 9 and Figure 10, which refer to Nyquist and Bode impedance modulus diagrams (log |Z|=f (log ω)), respectively.The equivalent circuit model used in the treatment of experimental data is shown in Figure 11.Parameters Rccc and Qcc refer to the resistance and pseudo capacitance of the coating, respectively.Rct and Qdl refer to the charge transfer resistance and the double layer pseudo capacitance, respectively, and Rs corresponds to the solution resistance 65 .As seen in Figure 9, the Nyquist diagram of all the coatings shows a depressed semicircle shape.Considering that a larger diameter of the semicircle indicates a greater resistance to corrosion, Figure 9 shows that the coating containing 2% v/v of CNC-Sif is the one with the greatest corrosion resistance, while the lowest one was seen in the coating without the addition of the CNC-Sif.
Like the Nyquist diagram, the Bode impedance modulus diagram (Figure 10) can also be used to evaluate the corrosion resistance of the coating.In the high frequency region, above 2000 Hz, the log |Z| is smaller and tends to remain constant.This indicates a resistive response, which in turn corresponds to the solution resistance (Rs).In the intermediate frequency range, the |Z| decreases with increasing frequency.On the other hand, in the low frequency region, with values lower than 1Hz, the impedance behavior is associated with the polarization resistance and the higher impedance modulus indicates a higher polarization resistance and consequently greater corrosion resistance 66 .Therefore, Figure 10 also indicates that addition of the CNC-Sif increases the corrosion resistance of the coating and this effect is more significant in the presence of 2% v/v.The EIS results, as well as the results obtained from the polarization curves and the mass loss tests show that the addition of the CNC-Sif increases the corrosion resistance of the Zn-Ni coating.The optimal concentration, among the analyzed concentrations, is 2% v/v, at which the corrosion resistance is maximum.As can be seen in Figure 6, the results regarding the corrosion rate of the sample obtained in the presence of 4% v/v of nanocrystals are in the same margin of error as the corrosion rate corresponding to the sample obtained in the absence of the nanocrystals.However, electrochemical tests show that the addition of 4% v/v of the CNC-Sif increases the corrosion resistance of the Zn-Ni coating.This inconsistency may be due to a limitation of the mass loss measurements.This is related to the difficulty of completely removing the corrosion products from the samples after immersion in the aggressive solution.
Based on the results listed in Table 4, it is not possible to state that the decrease in the corrosion rate of the Zn-Ni coating is related to the increase in the Ni content in the coating.Although the addition of 2% v/v of CNC-Sif does result in a small increase in the Ni content, the addition of 3% v/v does not result in an increase in the Ni content and despite this, there is an increase in corrosion resistance in relation to the nanocrystal-free coating.As with ceramic nanoparticles, as seen in the introduction, the increase in the Zn-Ni corrosion resistance due to the addition of the CNC-Sif is probably related to the change in the morphology and structure of the coating caused by the incorporation of the nanocrystals.Therefore, investigations into the effect of the addition of CNC-Sif on roughness, texture coefficient, crystallite size, and microstrain help to understand the effect of this addition on the corrosion rate of the Zn-Ni coating.
Given their nanometric dimensions, the nanocrystals are small enough to fill defects, such as gaps and pores, making the coating surface smoother.This effect decreases the surface contact area with the corrosive solution, thus improving the corrosion resistance of the coating.Furthermore, the reduction in defects that could act as active corrosion sites also favors the increase in corrosion resistance.The smoothness of the surface can be evaluated through the measurement of roughness, with a lower roughness indicating a smoother surface, which favors an increase in corrosion resistance.Therefore, the decrease in roughness caused by the addition of the nanocrystals (Figure 2) may have contributed to the increase in the corrosion resistance of the Zn-Ni coating, and the sample with the lowest roughness is the one with the highest corrosion resistance.However, it has been found 36,46 that the addition of nanoparticles can lead to increased corrosion resistance, despite the fact that this addition results in increased roughness.This therefore indicates that the increase in the corrosion resistance of the metallic coating due to the addition of nanoparticles is also related to other factors.
The change in the presence of the crystallographic planes can affect the behavior of the metallic coating in relation to corrosion.In a more closely packed plane, the atoms are closer to each other, thus increasing the binding energy, favoring the corrosion resistance of the coating 48 .The increase in the presence of the γ(330) plane with the addition of 2% v/v and 3%v/v of CNC-Sif (Figure 3 and Figure 4) therefore favors an decrease in the corrosion rate of the coating, considering that this plane exhibits a more closely packed surface.The higher corrosion resistance of the coating containing 2% v/v CNC-Sif is consistent with the fact that it has a higher TC.The increase in the presence of the η(101) plane to the detriment of the γ(330) plane with the addition of 4% v/v may have contributed to the lower corrosion resistance of the coating compared to the samples containing 2% v/v and 3% v/v.However, the fact that the coating containing 4% v/v exhibits a superior corrosion resistance than the coating without CNC-Sif, despite the fact that this coating has a greater presence of the γ(330) plane, indicates that the presence of the crystallographic plane is not the factor determining the effect of the nanocrystals on the corrosion resistance of the Zn-Ni coating.
The refining of metallic coating grains is often related to increased corrosion resistance of a metallic coating 67,68 .Therefore, considering that the decrease in crystallite size indicates the occurrence of grain refining, the results obtained in the present work are consistent with the fact that the addition of the nanocrystals causes both the refining of crystallites and an increase in the corrosion resistance of the coating.Even the coating containing 2% v/v of CNC-Sif, which is the one with the highest corrosion resistance, is the one with the highest grain refinement.The effect of grain refining in increasing the corrosion resistance of the coating is attributed to a greater dispersion of the corrosion current, which results in a lower occurrence of localized corrosion 67 .However, it is not clear how this current density dispersion occurs due to grain refining.
Microstrain can affect the corrosion rate of the coating because the increase in microstrain can cause cracking which results in the deterioration of the coating's corrosion resistance.As observed in Table 6, the addition of the CNC-Sif increases the microstrain of the coating, however, this increase was not enough to affect the corrosion rate of the coating, and the coating containing 2% v/v, which exhibits a higher microstrain, is the one that presents a greater resistance to corrosion.
In addition to the effect of the presence of the nanocrystals on the microstructure and morphology of the coating, the increase in corrosion resistance may be related to other effects as mentioned earlier (see Introduction).It is possible that the incorporation of the nanocrystals in the coating results in a decrease in the active surface in contact with the corrosive solution, thus increasing the corrosion resistance of the coating 15 .As suggested in relation to the incorporation of graphene oxide 69 and silica nanoparticles 70 , it is also possible that the incorporation of nanocrystals hinders the diffusion of oxygen, thus inhibiting the reduction reaction with the consequent increase in corrosion resistance.By presenting a low level of electrical conductivity, it is also possible that nanocrystals, when uniformly dispersed in the coating, cause an increase in the resistance to current flow, in addition to promoting the distract of this current flow 44,71 .
As mentioned in the Introduction regarding TiO2 and CeO2 nanoparticulates incorporated in the Ni-P coating, it is also possible that the presence of nanocrystals favors uniform corrosion at the expense of localized corrosion, thus making the coating more resistant to corrosion.This effect is attributed to the introduction of corrosion microcells with the nanoparticle acting as the cathode and the Zn-Ni matrix as the anode, which results in a more uniform distribution of corrosion 72 .
The effect of the nanocrystal concentration on the corrosion resistance of the Zn-Ni coating is probably related to the distribution of the nanocrystals in the coating because, as seen in item 3.2, this distribution affects the microstructure and morphology of the coating.With the increase in the CNC-Sif content above 2% v/v, which should result in a less uniform distribution and favor the agglomeration of the nanocrystals, there is an increase in roughness, in the size of the crystallites, and a decrease in the presence of the γ(330) plane, all of which can collaborate to reduce the corrosion resistance of the coating.In addition, a greater agglomeration of the nanocrystals decreases the intensity of the nanocrystal binding with the metallic matrix, which can cause the nanocrystals to be removed from the matrix, resulting in the formation of defects such as gaps and pores.These defects act as active corrosion sites favoring a decrease in the corrosion resistance of the coating 73 .
The distribution of the nanocrystals should also affect their efficiency in acting as a protective barrier against the action of the corrosive medium.As the agglomeration of nanocrystals occurs with increasing concentration, the distance between them increases, thus impairing the inhibitory action that they exert in relation to the diffusion of ions and the electric current.Furthermore, the increase in the size of the nanocrystals, resulting from the agglomeration, restricts their ability to fill the defects present in the coating, and therefore, to make the coating more compact and uniform.
In the present work, the effects resulting from the increase in the concentration of CNC-Sif from 2% v/v, which resulted in a decrease in corrosion resistance, were not sufficient to reduce the corrosion resistance of the Zn-Ni coating in relation to the absence of the additive.However, the results obtained show that there is an optimal content of additive, and that for higher levels it is possible that the addition of the nanocrystals results in the deterioration of the corrosion resistance of the coating.It can also be seen that the mechanisms through which the addition of the nanocrystals affects the corrosion resistance of the Zn-Ni coating are complex and it is not possible to determine what the predominant mechanism might be.
Ni is added to the Zn-Ni alloy in order to decrease the alloy's corrosion rate, but it has a higher cost than Zn.Therefore, increasing the corrosion resistance of Zn-Ni through the addition of a relatively low cost additive such as CNC-Sif is important because it reduces the Ni content required in the alloy.In a future work, the effect of the addition of CNC-Sif on the corrosion resistance of Zn-Ni coatings containing different concentrations of Ni will be analyzed in order to determine how much the concentration of Ni in the coating can be reduced with the addition of CNC-Sif.
It is also important to mention that in nanocomposites containing ceramic nanoparticles, surfactants are often added to minimize the agglomeration of the nanoparticles and consequently increase the corrosion resistance of the coating.For example, the surfactant cetyl trimethyl ammonium bromide is added to the deposition bath of the Zn-Ni coating to minimize the agglomeration of TiO2 nanoparticles 74 .Therefore, in a future work, the effect of the presence of a surfactant on the agglomeration of the CNC-Sif will be analyzed.

Effect of the addition of sisal nanocrystals on the microhardness of the Zn-Ni coating
The microhardness values of the Zn-Ni coatings in the absence and presence of different levels of the CNC-Sif are shown in Figure 12.These results show that the addition of the nanocrystals increases the microhardness of the coating, and the highest microhardness value corresponds to the coating obtained in the presence of 2%v/v of the CNC-Sif.Although the behavior of the coating in relation to wear resistance must be analyzed through specific tests, the increase in hardness indicates a tendency to increase wear resistance which is an important characteristic in the application of the coating.Electrodeposited Zn-Ni-sisal Nanocrystals Composite Coatings -Morphology, Structure and Corrosion Resistance According with Praveen and Venkatesha 74 an increase of around 9% in microhardness is a significant improvement in applications of the coatings at an industrial scale.It is observed in Figure 12 that the addition of 2%v/v of the CNC-Sif results in an increase of at least 20% in the microhardness of coating.
The increase in the microhardness of coating due to the addition of nanoparticles has also been observed with the addition of ceramic nanoparticles such as SiO2 and TiO2 [75][76][77][78] .This effect is mainly attributed to grain refining, dispersion-strengthening 53 and, the high hardness of the nanoparticles that inhibits the deformation of the coating matrix (particle-strengthening) 75 .Due to the low hardness of the natural polymer, the addition of CNC-Sif should collaborate to reduce the microhardness of coating, however the results indicate that the effects of grain refining and dispersion-strengthening prevail.
As observed in Table 6, the addition of 2% v/v and 3% v/v of the CNC-Sif decreases the size of the crystallites, which may indicate a grain refining.Therefore, it is possible that the increase in microhardness with the addition of these nanocrystal concentrations is related to the decrease in grain size.Grain refining implies an increase in the area of the grain boundary, which hinders the movement of dislocations with the consequent increase in microhardness.Dispersionstrengthening is an important mechanism in increasing the microhardness of the coating due to the presence of nanoparticles 76 .It is possible that due to their small size, the CNC-Sif nanocrystal interact with the dislocations, resulting in increased microhardness.
The lower microhardness of coating with the addition of 3% v/v and 4%v/v compared to the addition of 2% v/v may be related to the increase in the agglomeration level of the nanocrystals, which results in a decrease in the number of nancrystal per coating volume.Therefore, with the increase in nanocrystal concentrations from 2% v/v, the effect of dispersion-strengthening and grain refining on the increase in microhardness becomes less intense.The microhardness results are consistent with results referring to current efficiency and corrosion resistance, which show that these properties are better with the addition of 2% v/v and deteriorate with increasing CNC-Sif concentration, probably due to the agglomeration of these nanocrystals.
In prior work it was found that the addition of cotton nanocrystal 9 and soybean nanocrystal 8 to the Zn coating reduces the hardness of the coating.This effect is attributed to the presence of weak interfacial bonding strength between the nanocrystals and the matrix collaborating to decrease the hardness of the coating.However, the results obtained in relation to the effect of CNC-Sif on the microhardness of Zn-Ni coating in the present work, show that the interfacial bonding strength between the nanocrystals and the matrix depends on the nanocrystal.
The addition of the CNC-Sif in the deposition bath affects the morphology and structure of the Zn-Ni coating, and this effect is more pronounced with the addition of 2% v/v of nanocrystals.
There is a decrease in roughness, and with the exception of the concentration of 4% v/v, there is a decrease in the size of the crystallites and an increase in the microstrain, favoring the presence of γ(330) planes.
The current efficiency is increased with the addition of the sisal nanocrystals up to a concentration of 3% v/v, and this effect is more significant with the addition of 2% v/v.
The corrosion resistance of the Zn-Ni coating is increased with the addition of CNC-Sif in the deposition bath.It was found that there is an optimal content of nanocrystals, namely 2% v/v, at which corrosion resistance is maximum.This is related to the effect of the nanocrystals on the morphology and structure of the Zn-Ni coating.
The addition of the nanocrystals increases the microhardness of the coating, and the highest microhardness value corresponds to the coating obtained in the presence of 2%v/v of the CNC-Sif

Figure 2 .
Figure 2. Two-dimensional topographical images from confocal microscopy of the Zn-Ni coatings obtained in the absence and presence of varying levels of CNC-Sif.

Figure 3 .
Figure 3. X-ray diffractogram pattern of the Zn-Ni coating obtained in the absence and presence of various concentrations of CNC-Sif.

Figure 4 .
Figure 4. Texture coefficient of the Zn-Ni coating obtained in the absence and presence of varying concentrations of CNC-Sif.

Figure 5 .
Figure 5. Current efficiency of the electrodeposition process of a Zn-Ni coating obtained in the absence and presence of varying amounts of CNC-Sif.

Figure 6 .
Figure 6.Corrosion rate obtained from mass loss tests of Zn-Ni coatings obtained in the absence and presence of varying levels of CNC-Sif.

Figure 7 .
Figure 7. Potentiodynamic polarization curves in the 0.5 M NaCl solution of the Zn-Ni coatings obtained in the presence of varying concentrations of CNC-Sif added to the bath deposition.The curves were obtained at a scanning rate of 10 mV/s.

Figure 8 .
Figure 8. Polarization resistance of Zn-Ni coating obtained in the absence and presence of different concentrations of CNC-Sif.

Figure 9 .
Figure 9. Nyquist plot in 0.5M NaCl solution for Zn-Ni coatings obtained in the absence and presence of varying concentrations of CNC-Sif.

Figure 10 .
Figure 10.Bode plot in 0.5M NaCl solution for Zn-Ni coatings obtained in the absence and presence of varying concentrations of CNC-Sif.

Table 7 .
Corrosion potential, E cor , in 0.5 M NaCl solution of Zn-Ni coating obtained in the absence and in the presence of varying levels of CNC-Sif.

Figure 11 .
Figure 11.Equivalent electrical circuits used for the analysis of impedance spectra.

Figure 12 .
Figure 12.Microhardness values of the Zn-Ni coatings in the absence and presence of different levels of the CNC-Sif.

Table 1 .
25aracteristics of CNC-Sif, where L corresponds to the length, and D to the diameter of the nanocrystals25.

Table 2 .
Composition of bath deposition used to obtain the Zn-Ni coating.

Table 3 .
pH and electrical conductivity of the deposition bath without and with different nanocrystal concentrations.

Table 5 .
Roughness parameters of Zn-Ni coating in the absence and presence of different levels of CNC-Sif, where: Sa corresponds to the arithmetic mean of the absolute value of the surface departure above and below the mean plane within the sampling area, Sp to the height of the highest peak within the defined area, and Sv to the depth of the deepest valley within the defined area.

Table 6 .
Crystallite size and microstrain values of Zn-Ni coating obtained in the absence and presence of varying concentrations of CNC-Sif.