Various surface characterization techniques were used
to study
the modified surface chemistry of superhydrophobic aluminum alloy
surfaces prepared by immersing the substrates in an aqueous solution
containing sodium hydroxide and fluoroalkyl-silane (FAS-17) molecules.
The creation of a rough micronanostructure on the treated surfaces
was revealed by scanning electron microscopy (SEM). X-ray photoelectron
spectroscopy (XPS) and infrared reflection absorption spectroscopy
(IRRAS) confirmed the presence of low surface energy functional groups
of fluorinated carbon on the superhydrophobic surfaces. IRRAS also
revealed the presence of a large number of OH groups on the hydrophilic
surfaces. A possible bonding mechanism of the FAS-17 molecules with
the aluminum alloy surfaces has been suggested based on the IRRAS
and XPS studies. The resulting surfaces demonstrated water contact
angles as high as ∼166° and contact angle hystereses as
low as ∼4.5°. A correlation between the contact angle,
rms roughnesses, and the chemical nature of the surface has been elucidated.
A simple one-step process has been developed to render aluminum alloy surfaces superhydrophobic by immersing the aluminum alloy substrates in a solution containing NaOH and fluoroalkyl-silane (FAS-17) molecules. Scanning electron microscopy (SEM), X-ray photoelectron spectroscopy (XPS) and water contact angle measurements have been performed to characterize the morphological features, chemical composition and superhydrophobicity of the surfaces. The resulting surfaces provided a water contact angle as high as ∼162° and a contact angle hysteresis as low as ∼4°. The study indicates that it is possible to fabricate superhydrophobic aluminum surfaces easily and effectively without involving the traditional two-step processes.
Structural adhesive bonding of aluminum is widely used in aircraft and automotive industries. It has been widely noted that surface preparation of aluminum surfaces prior to adhesive bonding plays a significant role in improving the strength of the adhesive bond. Surface cleanliness, surface roughness, surface wettability and surface chemistry are controlled primarily by proper surface treatment methods. In this study, we have employed a very simple technique influencing all these criteria by simply immersing aluminum substrates in a very dilute solution of sodium hydroxide (NaOH) and we have studied the effect of varying the treatment period on the adhesive bonding characteristics. A bi-component epoxy adhesive was used to join the treated surfaces and the bond strengths were evaluated via single lap shear (SLS) tests in pristine as well as degraded conditions. Surface morphology, chemistry, crystalline nature and wettability of the NaOH treated surfaces were characterized using various surface analytical tools such as scanning electron microscopy and energy dispersive X-ray analysis (SEM/EDX), optical profilometry, infrared reflection absorption spectroscopy, Xray photoelectron spectroscopy, X-ray diffraction and contact angle goniometry.Excellent adhesion characteristics with complete cohesive failure of the adhesive were encountered on the NaOH treated surfaces that are comparable to the benchmark treatments such as anodization, which involve use of strong acids and multiple steps of treatment procedures. The NaOH treatment reported in this work is a very simple method with the use of a very dilute solution with simple ultrasonication being sufficient to produce durable joints.
Graphical AbstractHighlights A very simple surface treatment method to achieve excellent and durable aluminum adhesive bonding. Our method involves simple immersion of aluminum in very dilute NaOH solution at room temperature with no involvement of strong acids or multiple procedures. Surface analysis via various surface characterization techniques showed morphological and chemical modifications favorable for obtaining highly durable bond strengths on the treated surface. Safe, economical, reproducible and simple method, easily applicable in industries.
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