Chun Yat Lau scite author profile

In this work, 2 μL water drops are placed on substrates that are created to have a circular hydrophilic region bounded by superhydrophobicity so that they exhibit high contact angles. When the substrate is translated by a linear stepper actuator, the random force components present in the actuator are shown to cause the drop to rock resonantly. When the substrate is translated downward at inclination angles of up to 6° with respect to the horizontal, the contact angle hysteresis increases progressively to a limiting condition. When the substrate is moved up at inclined angles, alternatively, the contact angle hysteresis increases initially to the limiting condition before it is progressively restored to its static state. These behaviors are accounted for by the reversible micro-Cassie to Wenzel wetting state transformations that are made possible by the hierarchical microscale and nanoscale structures present in the superhydrophobic regions.

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Graphite flake self-retraction response based on potential seeking

Lau

Bernados-Chamagne

et al. 2012

Nanoscale Res Lett

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The high elastic modulus and interlayer strengths of graphite flakes make them a durable solid superlubricant. Apart from this, they have configurable electrical properties, exhibit quantum Hall effects, and possess a myriad of useful photonic properties. The self-retraction behavior of graphite flakes can have significant impact on the creation of ordered stacks for various applications because any accidental or intentional displacement of the top flake over the stacks below may result in a misalignment of the carbon-carbon atomic arrangement which, in turn, can have influence over the electrical and photonic properties. It has also been revealed that there was a tendency of the displaced microflake to fail at times to return to its original starting position and orientation. Here, we elucidate this behavior by considering the influence of the interlayer potential forces based on minimal potential energy seeking. The maps of the parameters interrogated here provide the ability for precautions to be undertaken. They also potentially permit the creation of an array of microflake stacks in which the metastable states permit different information to be encoded by virtue of the differentiated photonic or electrical characteristics readable from each array site.

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Antibody drop based handling with near-superhydrophobic mesh substrates overcomes condensation sticking

Chung

Katariya

Zahidi

et al. 2019

Materials Science and Engineering: C

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Chun Yat Lau

A direct heating model to overcome the edge effect in microplates

Hydrophobic to superhydrophobic surface modification using impacting particulate sprays

Linear Stepper Actuation Driving Drop Resonance and Modifying Hysteresis

Graphite flake self-retraction response based on potential seeking

Antibody drop based handling with near-superhydrophobic mesh substrates overcomes condensation sticking

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