Bouncing Droplets: A Hands-On Activity To Demonstrate the Properties and Applications of Superhydrophobic Surface Coatings

Cionti, Carolina; Taroni, Tommaso; Meroni, D.

doi:10.1021/acs.jchemed.9b00406

Cited by 5 publications

(6 citation statements)

References 34 publications

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Section: ■ Introductionmentioning

confidence: 99%

“…Previously published work has explored the measurement of contact angles in education settings, on samples ranging from hydrophilic to both natural and artificially created hydrophobic surfaces. ,− However, the measurement of contact angles is typically done either qualitatively with the naked eye (such as by observing the droplet roll off the surface) or using an associated laboratory’s contact angle goniometer. , While there exist some examples of the construction of less complex goniometers, these still require additional components, such as microscopes and lenses, which may be less available to educators. , With our approach, the measurement of contact angles on various surfaces, including hydrophilic surfaces as well as naturally occurring and artificial hydrophobic materials, can be accomplished wholly within the classroom setting, allowing students the opportunity to collect and analyze quantitative data. Additionally, as this device is a generally applicable tool for contact angle measurements, a wide range of samples with differing liquids and solid surfaces may be observed in addition to water, and thus, it is useful across multiple educational levels as a means to easily explore differing depths of understanding regarding surface chemistry.…”

Section: Introductionmentioning

confidence: 99%

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Designing and 3D Printing an Improved Method of Measuring Contact Angle in the Middle School Classroom

Crowe

Hendrickson-Stives

Kuhn³

et al. 2021

J. Chem. Educ.

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The interaction between water and surfaces is observed in our daily lives and is used in laboratories to study materials properties, such as interfacial tension. Making the connection between fundamental scientific phenomena and everyday observations is a powerful method of highlighting the importance and relevance of science to the K−12 population. Typically, expensive equipment, such as dedicated contact angle goniometers, is used in laboratories to observe how water interacts with materials. Obtaining such laboratory-grade equipment for the K−12 classroom is not only difficult but also unnecessary. Thus, we present an affordable 3D printed setup for the reliable measurement of the contact angle of water on a variety of natural and synthetic surfaces, using smart devices (e.g., cell phone, tablet) as the imaging basis. This setup enables proper backlighting, a stable camera holder for quality images, and a flat surface with an easily adjustable platform to hold the sample. Compared to simply holding the smart device by hand, the 3D printed method provided better quality images and an improved data acquisition experience when measuring the contact angle. Use in a middle school setting has shown that this 3D printed method is successful for teaching about water/surface interactions on both hydrophilic and hydrophobic surfaces. This method can easily be adapted to suit learning objectives, allowing educators to explore a range of hydrophobic and hydrophilic surfaces of both biological and synthetic origin.

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Section: ■ Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Designing and 3D Printing an Improved Method of Measuring Contact Angle in the Middle School Classroom

Crowe

Hendrickson-Stives

Kuhn³

et al. 2021

J. Chem. Educ.

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“…30,32 Experiments utilizing commonly found patterned objects such as the surfaces of recordable compact disks (CD-R) have also been described. 31,32 Further laboratory exercises have utilized carbon soot, 33 methyltrichlorosilane, 34 TiO 2 nanoparticles, 35,36 and electroless deposited copper particles 37 to provide texturation. For instance, Kabza and co-workers designed a laboratory exercise that enabled students to calculate the critical surface energy of readily available materials such as glass and polytetrafluoroethylene (PTFE) using Zisman plots.…”

Section: ■ Introductionmentioning

confidence: 99%

Thermodynamics of Wettability: A Physical Chemistry Laboratory Experiment

et al. 2022

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In this laboratory experiment, students modify a series of surfaces and explore the effects of varying surface chemistry and texture on wettability by different probe liquids. Students begin by building a simple contact angle goniometer utilizing their mobile phone cameras. Next, they contrast the wettability of planar glass substrates functionalized with alkyl silanes and fluorinated alkyl silanes and calculate surface free energies using Owens/Wendt plots. Subsequently, they synthesize ZnO tetrapods as robust textural elements and spray deposit the tetrapods onto stainless steel meshes to develop hierarchical texturation, which upon subsequent surface functionalization yields superhydrophobic and oleophobic surfaces. The series of experiments allow them to investigate the manner in which textured surfaces deviate from Young's equation and provide a vivid illustration of the thermodynamics of surface wettability. The laboratory exercise further provides a striking visual analogy for illustrating free energy landscapes and serves as a tangible means to demonstrate the role of surface chemistry with regards to the midstream oiltransportation infrastructure.

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“…Understanding droplet impact behavior onto various surfaces is crucial for a wide range of applications, including 3D and inkjet printing, combustion, spray cooling, anti-icing surfaces, agriculture, forensic assay, and coating processes. − Different factors for controlling droplet impact dynamics on various surfaces have been extensively investigated, including the impact regime, contact time (CT), maximum spreading radius, and rebounding angle. , Advances in smart materials, micro and nanoscale structures, and surface fabrication techniques have led to passive surface modification methods that can be used to modify surfaces for different applications. − For example, hydrophilic surfaces have been made to maximize the contact area upon impact, desirable for coating, flash cooling, and ink-jetting applications. , On the other side of the spectrum, superhydrophobic surfaces are used for anti-icing and anti-erosion applications to reduce the solid–liquid contact time during droplet impact. − However, various problems have been reported for these surfaces, such as three-phase contact line (TPCL) pinning, poor mechanical resilience, degradation of wetting properties over time, or low transparency. − Inspired by the Nepenthes pitcher plant structure, slippery liquid-infused porous surfaces (SLIPS) have been developed to achieve highly smooth and pinning-free surfaces. , SLIPS can be manufactured by imbibing porous and superhydrophobic nanostructures with a lubricating liquid (typically oil), which preferentially wets the solid and is immiscible to the contacting liquid of interest . These surfaces benefit self-cleaning and anti-icing applications as they can reject various impacting liquids, not exclusively water-based. ,, In addition, as long as the lubricant is present and coats the top of the porous medium, the SLIPS’s properties are expected to be sustained .…”

Section: Introductionmentioning

confidence: 99%

Surface Acoustic Waves to Control Droplet Impact onto Superhydrophobic and Slippery Liquid-Infused Porous Surfaces

Biroun

Haworth

Agrawal

et al. 2021

ACS Appl. Mater. Interfaces

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Superhydrophobic coatings and slippery liquid-infused porous surfaces (SLIPS) have shown their potentials in self-cleaning, anti-icing, antierosion, and antibiofouling applications. Various studies have been done on controlling the droplet impact on such surfaces using passive methods such as modifying the lubricant layer thickness in SLIPS. Despite their effectiveness, passive methods lack on-demand control over the impact dynamics of droplets. This paper introduces a new method to actively control the droplet impact onto superhydrophobic and SLIPS surfaces using surface acoustic waves (SAWs). In this study, we designed and fabricated SLIPS on ZnO/aluminum thin-film SAW devices and investigated different scenarios of droplet impact on the surfaces compared to those on similar superhydrophobic-coated surfaces. Our results showed that SAWs have insignificant influences on the impact dynamics of a porous and superhydrophobic surface without an infused oil layer. However, after infusion with oil, SAW energy could be effectively transferred to the droplet, thus modifying its impact dynamics onto the superhydrophobic surface. Results showed that by applying SAWs, the spreading and retraction behaviors of the droplets are altered on the SLIPS surface, leading to a change in a droplet impact regime from deposition to complete rebound with altered rebounding angles. Moreover, the contact time was reduced up to 30% when applying SAWs on surfaces with an optimum oil lubricant thickness of ∼8 μm. Our work offers an effective way of applying SAW technology along with SLIPS to effectively reduce the contact time and alter the droplet rebound angles.

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Bouncing Droplets: A Hands-On Activity To Demonstrate the Properties and Applications of Superhydrophobic Surface Coatings

Cited by 5 publications

References 34 publications

Designing and 3D Printing an Improved Method of Measuring Contact Angle in the Middle School Classroom

Designing and 3D Printing an Improved Method of Measuring Contact Angle in the Middle School Classroom

Thermodynamics of Wettability: A Physical Chemistry Laboratory Experiment

Surface Acoustic Waves to Control Droplet Impact onto Superhydrophobic and Slippery Liquid-Infused Porous Surfaces

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