FABRICATION OF CU-ZN SUPERHYDROPHOBIC COATING ON STEEL WITH PULSED CURRET ELECTRODEPOSITION TECHNIQUE: CURRENT DENSITY AND DUTY CYCLE VARIATION
???? Steel is prone to corrosion due to its main component is iron, which has a relatively low reduction potential. One of the primary factors causing corrosion in steel is the presence of a thin layer of water from the surrounding environment on the steel surface. To prevent this, a protective...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/75916 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | ????
Steel is prone to corrosion due to its main component is iron, which has a relatively
low reduction potential. One of the primary factors causing corrosion in steel is the
presence of a thin layer of water from the surrounding environment on the steel
surface. To prevent this, a protective coating with superhydrophobic properties with
a water contact angle > 150° to minimize water contact, is needed. One of many
techniques used to fabricate a superhydrophobic coating is electrodeposition. By
employing pulsed current with specific on-off cycles during electrodeposition, a
more compact coating can be obtained. This research aims to study the influence of
current density and duty cycle on the water contact angle values of the fabricated
superhydrophobic coating using pulsed current electrodeposition on API 5L X52m
steel with a Cu-Zn anode.
Before the fabrication of superhydrophobic coatings, all samples were prepared.
The fabrication process was conducted in two stages using the pulsed current
electrodeposition technique with variations of 1,6;2;3 A/dm2 in current density and
variation of 30%, 50%, and 70% in duty cycle, and carried out for 60 minutes with
a frequency of 250 Hz. The process was then followed by solution immersion for
30 minutes to obtain a micro-nano hierarchical structure. Then, the samples were
immersed in myristic acid solution for 36 hours to reduce the surface tension. Then,
water contact angle measurement was performed. The surface characteristics of the
superhydrophobic coatings were observed using scanning electron microscope and
X-ray diffraction. Then, electrochemical tests, immersion tests, self-cleaning tests,
and mechanical durability tests were performed.
The fabrication results showed the highest water contact angle of 160.609°, which
was achieved using a current density of 3 A/dm2 and a duty cycle of 30%. However,
the water contact angle tended to decrease after being exposed to atmospheric air
for 21 days. The surface morphology of coating film exhibited a micro-nano
hierarchical structure with micro and nano structure sizes approximately ±5.54 ?m
and ±750-860 nm. The formed phases on the coating surface were identified as
ZnO, CuO, and Cu-Zn. The corrosion potential and corrosion current density values
were -0.395 V vs Ag/AgCl and 46.519 ?A/dm2, respectively. The appropriate
equivalent circuit model indicated the presence of a protective layer at the metalenvironment
interface. The superhydrophobic layer was resistant to a corrosive
environment containing 3.5% NaCl, but the hydrophobic properties decreased. The
fabricated superhydrophobic layer also exhibited self-cleaning properties and
reasonably good mechanical resistance. |
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