International Journal of Engineering Materials and Manufacture (2016) 1(2) 71-74 

https://doi.org/10.26776/ijemm.01.02.2016.05 

 

J. Norhasnidawani, H. N. Azlina , H. Norita, and M. H. Ani 

Department of Manufacturing and Materials Engineering 

International Islamic University Malaysia 

PO Box 10, 50728 Kuala Lumpur, Malaysia 

E-mail: noorazlina_hassan@iium.edu.my 

 

Reference: J. Norhasnidawani, H. N. Azlina, H. Norita, and Hanafi Ani (2016). Effect of Nanoparticles on Wettability of 

Nanocoating on Carbon Steel. International Journal of Engineering Materials and Manufacture, 1(2), 71-74. 

 

 

Effect of Nanoparticles on Wettability of Nanocoating on Carbon Steel 

 

 

Norhasnidawani Johari, Noor Azlina Hassan, Norita Hassan, and Mohd Hanafi Ani 

 

 

Received: 28 November 2016 

Accepted: 15 December 2016 

Published: 20 December 2016 

Publisher: Deer Hill Publications 

© 2016 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

Nanocoatings plays an important role in coating industry. The great potential of nanocoatings was studied due to an 

excellent adhesion strength and corrosion protection of carbon steel. Nanocoatings was formulated through 

copolymerization of epoxy resin with the incorporation of Zinc Oxide (ZnO) and Silica (SiO2) nanoparticles. ZnO 

and SiO2 were synthesized using sol-gel technique. Epoxy acted as host while the nanoparticles incorporate as guest 

components. The performance of wetting ability with different medium was analysed using contact angle. Water 

medium showed the addition of 3wt% of hybrid between ZnO and SiO2 was the best nanocoating to form 

hydrophobic surface and was also the best nanocoating surface to form hydrophilic surface with vacuum oil dropping. 

The contact angle was smaller than 90° in oil dropping. 

 

Keywords: Zinc Oxide (ZnO), Silica (SiO2), Nanoparticles, Contact Angle, Nanocoating, Carbon steel 

 

 

1 INTRODUCTION 

Nanocoatings market is envisaged to grow over the next 5 to 10 years across all market segments. This is attributed 

to growing need for better facilities and advances in nanocoatings technology. This industry is segmented by type of 

future markets that includes anti-bacterial, anti-fouling, anti-fingerprint, easy to maintain and self-cleaning 

nanocoatings [1]. Potential applications such as self-cleaning increasing interest in wettability concerns. Wettability is 

one of the important characteristics that determine the properties of final coating [2]. 

The degree of wetting when a solid and liquid interact is determined by measurements of contact angle. Surface 

with low wettability shows the contact angles (<90°) while large contact angle is (>90°) corresponding to high 

wettability [3]. Steel is widely used for construction especially in heavy industries such as in the petrochemical, marine, 

and etc that exposed to corrosion [4]. 

Sol-gel hybrid coatings of organic and inorganic materials can combine the mechanical toughness and flexibility 

of organic components with the thermal stability and hardness of inorganic components [5]. Epoxy (organic) coating 

is a type of common organic coatings used to protect metal against corrosion. Research by Armelin [6] reported that 

the benzene rings in epoxy giving good properties such as resistance to chemical, good mechanical properties, thermal 

stability and good adhesion make it widely used for protective coatings. 

The epoxy contains ring opening during curing time. The hydrophobic and hydrophilic group in epoxy structure 

increases the adhesion properties.  The epoxy molecule is combined with a hardener material and effect crosslinking 

during curing or hardening [7]. ZnO is used as nanoparticles increased the adhesion and absorption of the UV 

radiation can stop solar degradation. The UV light is transform into vibration and heat [8]. The incorporation of 

silica nanoparticles provides better adhesion since nanoparticles acted denser and compact structure in the coating. 

The coating having good properties with solid and protective network layer when the nanoparticles are uniformly 

distributed throughout the coating. The nanoparticles function as elastomeric structure within the coating [9]. This 

research discussed on the wetting ability when deionised water and vacuum oil come into contact with the carbon 

steel. 

 

 

 



Effect of Nanoparticles on Wettability of Nanocoating on Carbon Steel 

72 

2 METHODOLOGY 

The nanoparticles was synthesized by using sol gel method. There were 18 pieces of carbon steels used in the study. 

The surfaces of samples were ground and polished with a manual hand grinder machine. The samples were then 

rinsed in distilled water and dried with acetone to remove traces of water. This step was conducted quickly to avoid 

premature corrosion. Brushing technique was used to coat the samples. Before coating, the epoxy was blend with 

hardener and stirred at 500rpm for 5 minutes, using overhead stirrer. Nanoparticles powder was poured right after 

and continuously stirred for another 5 minutes to obtain homogeneous mix. After mixing, the modified epoxy coating 

was then applied onto carbon steel coupons. The coupons were left to dry overnight in fume cupboard at room 

temperature. Then, the effect of nanoparticles on wetting ability was measured using contact angle. The conditions 

of testing are listed in Table 1. 

 

3 RESULTS AND DISCUSSION 

3.1 Deionized Water Dropping 

There was attraction between the solid and liquid on the surface influenced by surface energy. Based on Figures 1, 

deionized water drop on carbon steel surface showed that partial wetting occurred. This condition is known as 

hydrophobic or water hating. The contact angle of water droplet on surface is between 71° to 77°. The contact angle 

of liquid drop is based on the adhesive forces between the liquid and the surface [9]. 

The adhesives force was repelled and a liquid drop minimizes its contact with the surface. It was called 

hydrophobic where the area of solid surface decreased. Incorporation of nanoparticles into coating increased the 

degree of contact angle. This showed that ZnO and SiO2 nanoparticles was effectively imparting hydrophobic 

properties to the steel surface and determining the corrosion behaviour of the surface. Foreign particles were also 

repelled from the coating surface due to high contact angle. It shows that the wetting energy is getting smaller and 

become more hydrophobic [10]. Figure 1 show micrograph images of water dropping on nanocoating surface. 

Addition of 3wt% ZnO+2wt%SiO2 (hybrid) was the best formulation of nanocoating to form hydrophobic surface 

with good work of adhesion. Table 2 summarized the contact angle behaviour on different surface of nanocoating 

through deionized water dropping analysis. 

 

 

 

                            (a)                                                   (b)                                                    (c) 

 

                            (d)                                                   (e)                                                    (f) 

 

                           (g)                                                    (h)                                                    (i) 

 

Figure 1: Micrograph images of water dropping on nanocoating: (a) Plain Epoxy; (b) 2wt% ZnO; (c) 3wt% ZnO; 

(d) 2wt% SiO2; (e) 3wt% SiO2; (f) 1wt% ZnO+4wt% SiO2; (g) 2wt% ZnO+3wt% SiO2; (h) 3wt% ZnO+2wt% 

SiO2; (i) 4wt% ZnO+1wt% SiO2 

 

3.2 Vacuum Oil Dropping 

Oil molecules have low surface tension and stronger attraction to the molecules of the solid surface.  This shows that, 

the adhesive force is stronger than cohesive forces. Vacuum oil dropping onto carbon steel showed that there are 

strong adhesive forces on nanocoating surfaces due low surface tension and increases the area of solid surface contact 

[11]. This type of surface is called partial wetting or water loving. Incorporation of nanoparticles improved the ability 

of coatings and improved the adhesion between coating and substrate [12].  

In the case of vacuum oil dropping analysis nanocoating allows liquids to spread on surface due to low surface 

tension. The contact angle is less than 90°, as shown in Figure 2, shows that the oil drop spreads out and wet the 

surface. Figure 2(h), exhibit the lowest contact angle among all due to strong adhesive forces. It showed that in 

marine applications, when there was attraction between surface and coatings, adding another layer of nanocoating 

was enough after certain period of time. Table 3 summarized the contact angle, wetting energy and work of addition 

on different surface of vacuum oil dropping. 



Norhasnidawani et al., (2016): International Journal of Engineering Materials and Manufacture, 1(2), 71-74 

 

73 

Table 1: Selected condition during contact angle testing 

 

Properties (Unit) Water Oil 

Rec. Temperature (
0
C) 20 20 

Syringe Temperature (
0
C) 20 20 

Drop Volume (L) 18.3 0.65 

Rec. Time  05:54.8 53:28:4 

Rec. PosX (mm) 0 0 

Rec. PosY (mm) 0 0 

 

Table 2: Contact Angle of Nanocoating (Water Drop) 

 

Surface 

(wt%) 

Contact Angle 

(Degree) 

Wetting Energy 

(mN/m) 

Work of Adhesion 

(mN/m) 

Epoxy 72.71 21.64 94.44 

2ZnO(single) 77.96 15.18 87.98 

3ZnO(single) 73.38 20.83 93.63 

2SiO2(single) 73.05 21.23 94.03 

3SiO2(single) 75.31 18.46 91.26 

1ZnO+4SiO2(hybrid) 73.58 20.57 93.38 

2ZnO+3SiO2(hybrid) 74.88 18.99 91.79 

3ZnO+2SiO2(hybrid) 75.71 17.98 90.78 

4ZnO+1SiO2(hybrid) 75.86 17.78 90.58 

 

Table 3: Contact Angle of Nanocoating (Oil Drop) 

 

Surface 

(wt%) 

Contact Angle 

(Degree) 

Wetting Energy 

(mN/m) 

Work of Adhesion 

(mN/m) 

Epoxy 19.95 68.43 141.23 

2ZnO(single) 12.96 70.95 143.75 

3ZnO(single) 15.85 70.03 142.83 

2SiO2(single) 14.12 70.60 143.40 

3SiO2(single) 19.43 68.65 141.45 

1ZnO+4SiO2(hybrid) 12.76 71.00 143.80 

2ZnO+3SiO2(hybrid) 13.17 70.89 143.69 

3ZnO+2SiO2(hybrid) 11.51 71.34 144.14 

4ZnO+1SiO2(hybrid) 12.87 70.97 143.77 

 

 

 

                           (a)                                                    (b)                                                   (c) 

 

                           (d)                                                    (e)                                                    (f) 

 

                           (g)                                                    (h)                                                    (i) 

 

Figure 2: Micrograph images of vacuum oil dropping on nanocoatings: (a) Plain Epoxy; (b) 2wt% ZnO; (c) 3wt% 

ZnO; (d) 2wt% SiO2; (e) 3wt% SiO2; (f) 1wt% ZnO+4wt% SiO2; (g) 2wt% ZnO+3wt% SiO2; (h) 3wt% ZnO+2wt% 

SiO2; (i) 4wt% ZnO+1wt% SiO2 



Effect of Nanoparticles on Wettability of Nanocoating on Carbon Steel 

74 

4 CONCLUSIONS 

In this research study, adding nanoparticles into epoxy coating decreased the wetting energy and become more 

hydrophobic. Addition of 3wt% ZnO+2wt%SiO2 (hybrid) was the best nanocoating surface to form hydrophobic 

surface for deionized water dropping. For vacuum oil dropping, adding nanoparticles allowed liquids to spread on 

surface. Nanoparticles increased the ability of nanocoatings. There was improvement in adhesion of coating and 

carbon steel as a substrate. Addition of 3wt% ZnO+2wt%SiO2 (hybrid) was the best nanocoating surface to form 

hydrophilic surface with vacuum oil dropping. 

 

ACKNOWLEDGEMENT 

The authors acknowledge Ministry of Higher Education (MOHE) for Research Grant FRGS13-077-125-0318 for 

funding this research activities. The authors are grateful to the Materials Department Laboratory where the 

experimental studies were conducted. 

 

REFERENCES 

1. Thomas (2013). Market Research Study on Nanocoatings. Retrieve from: http://marketpublishers.com. 

2. Cabrera-Sierra, Sosa, E., Oropeza, M. T., & Gonzalez, I. (2012). Electrochemical study on carbon corrosion process 

in alkaline sour media. Electrochimia Acta, 47(13-14), 2149-2158. 

3. Armelin, E. (2011). Corrosion protection with polyaniline and polypyrole as anticorrosive additives for epoxy 

paint. Corrosion Science, 50(3), 721-728. 

4. Tan, A. L. K., & Soutar, A. M. (2008). Hybrid sol-gel coatings for corrosion protection of copper. Thin Solids 

Film, 516(16), 5706-5709. 

5. Atik, M., & Aegerter, M. A. (2009). Corrosion resistant sol-gel ZrO2 on stainless steel. Journal of Non-Crystalline 

Solids, 147-148, 236-241. 

6. Shen, G. X., Chen, Y. C., Lin C.J., & Scantleburry, D. (2012). Study on a hydrophobic nano TiO2 coating and its 

properties for corrosion protection of metals. Electrochimia Acta, 50(25-26), 5083-5089. 

7. Shang, J., Flury, M., James, B. H., & Richard, L. Zollars. (2008). Comparison of different methods to measure 

contact angles of soil colloids. Journal of Colloid and Interface Science, 328(2), 299-307.   

8. Phan, H. T., Caney, N., Marty, P., Colasson, S., & Gavillet, J. (2009). Surface wettability control by nanocoating: 

The effects on pool boiling heat transfer and nucleation mechanism. International Journal of Heat and Mass 

Transfer, 52(23-24), 5459-5471.  

9. Zhai, L.,
 

Fevzi, C. C., Robert, E. C., & Michael, F. R. (2004). Stable superhydrophobic coatings from 

polyelectrolyte multilayers. Nanoletters, 4(7), 1349-1353. 

10. Shen, G. X., Chen, Y. C., Lin, L., Lin, C. J. & Scantlebury, D. (2005). Study on a hydrophobic nano-TiO2 coating 

and its properties for corrosion protection of metals. Electrochimica Acta, 50(25-26), 5083-5089.  

11. Rosario, R.,
 
Gust, D.,

 
Antonio, A. G.,

 
Mark Hayes,

 
J. L., Taraci,

 
T. C.,

 
Dailey,

 
J. W. & Picraux, S. T. (2004). Lotus 

effect amplifies light-induced contact angle switching. Journal of Physical Chemistry B, 108(34), 12640-12642. 

12. Steele, A., Bayer, I., & Loth, E. (2009). Inherently superoleophobic nanocomposite coatings by spray atomization. 

Nanoletters, 9(1), 501–505.