Sessile-Water-Droplet Contact Angle Dependence on Adsorption at the Solid−Liquid Interface

Ghasemi, Hadi; Ward, C. A.

doi:10.1021/jp911259n

Cited by 38 publications

(35 citation statements)

References 38 publications

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“…Regarding the first phenomenon, it has been reported that a small tip‐to‐substrate distance combined with a 1:2 inner‐to‐outer tip diameters ratio cause the formation of larger meniscus, and as a result, a larger deposition area . Similarly, the larger base size can be attributed to a small tip‐to‐substrate distance and approach speed, as well as to the hydrophilic nature of Cu …”

Section: Resultsmentioning

confidence: 99%

Atomic Force Microscope‐Based Meniscus‐Confined Three‐Dimensional Electrodeposition

Eliyahu

Gileadi

Galun³

et al. 2020

Adv Materials Technologies

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The development of a 3D electrochemical deposition system, which combines meniscus‐confined electrodeposition (MCED) with atomic force microscope (AFM) closed‐loop control and has a submicron resolution, is described. Thanks to the high rigidity of the hollow borosilicate glass (or quartz) tip and quartz crystal tuning fork (QTF), combined with the QTF's high force sensitivity, the use of a solution‐filled AFM tip in air is successful. The AFM control enables full automation and in situ growth control. Using this scheme, 3D printing of high‐quality, fully dense, uniform and exceptionally smooth, freestanding straight and overhang pure polycrystalline copper pillars, with diameters ranging from 1.5 µm to 250 nm, and an aspect ratio > 100, is demonstrated. This process may be useful for manufacturing of high‐frequency terahertz antennas, high‐density interconnects, precision sensors, micro‐ and nano‐electromechanical systems, batteries, and fuel cells, as well as for repair or modification of existing micro‐sized or nano‐sized features.

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Section: Resultsmentioning

confidence: 99%

Atomic Force Microscope‐Based Meniscus‐Confined Three‐Dimensional Electrodeposition

Eliyahu

Gileadi

Galun³

et al. 2020

Adv Materials Technologies

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“…Solid tensions are not typically accessible to tensiometry (at least not without additional theory [14, 210] and the inevitable assumptions/simplifications embodied therein). Also, interpretation of solid interfacial tensions almost always depends on the reliability of the Young equation, which is of dubious merit for reasons mentioned in Section 6.1.…”

Section: 0 Energy and Mass Balance In Protein Adsorptionmentioning

confidence: 99%

Protein adsorption in three dimensions

2012

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Recent experimental and theoretical work clarifying the physical chemistry of blood-protein adsorption from aqueous-buffer solution to various kinds of surfaces is reviewed and interpreted within the context of biomaterial applications, especially toward development of cardiovascular biomaterials. The importance of this subject in biomaterials surface science is emphasized by reducing the “protein-adsorption problem” to three core questions that require quantitative answer. An overview of the protein-adsorption literature identifies some of the sources of inconsistency among many investigators participating in more than five decades of focused research. A tutorial on the fundamental biophysical chemistry of protein adsorption sets the stage for a detailed discussion of the kinetics and thermodynamics of protein adsorption, including adsorption competition between two proteins for the same adsorbent immersed in a binary-protein mixture. Both kinetics and steady-state adsorption can be rationalized using a single interpretive paradigm asserting that protein molecules partition from solution into a three-dimensional (3D) interphase separating bulk solution from the physical-adsorbent surface. Adsorbed protein collects in one-or-more adsorbed layers, depending on protein size, solution concentration, and adsorbent surface energy (water wettability). The adsorption process begins with the hydration of an adsorbent surface brought into contact with an aqueous-protein solution. Surface hydration reactions instantaneously form a thin, pseudo-2D interface between the adsorbent and protein solution. Protein molecules rapidly diffuse into this newly-formed interface, creating a truly 3D interphase that inflates with arriving proteins and fills to capacity within milliseconds at mg/mL bulk-solution concentrations CB. This inflated interphase subsequently undergoes time-dependent (minutes-to-hours) decrease in volume VI by expulsion of either-or-both interphase water and initially-adsorbed protein. Interphase protein concentration CI increases as VI decreases, resulting in slow reduction in interfacial energetics. Steady-state is governed by a net partition coefficient P=true(/CBCItrue). In the process of occupying space within the interphase, adsorbing protein molecules must displace an equivalent volume of interphase water. Interphase water is itself associated with surface-bound water through a network of transient hydrogen bonds. Displacement of interphase water thus requires an amount of energy that depends on the adsorbent surface chemistry/energy. This “adsorption-dehydration” step is the significant free-energy cost of adsorption that controls the maximum amount of protein that can be adsorbed at steady state to a unit adsorbent-surface area (the adsorbent capacity). As adsorbent hydrophilicity increases, protein adsorption monotonically decreases because the energetic cost of surface dehydration increases, ultimately leading to no protein adsorption near an adsorbent water wettability (surface energy) characterized ...

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“…1 (color online). In each experiment, an evaporating water droplet with a three-phase-line radius of 9 AE 0:01 mm was maintained on a polished Cu substrate (roughness 53 nm [19]) and in steady state by a syringe pump that injected deionized, degassed water into the droplet base through a small (0.6-mm-diameter) tube at the same rate that vapor was removed from the enclosing chamber. The droplet height and the temperature in the liquid and vapor phases were measured with a U-shaped thermocouple (25 m bead diameter) that was mounted on a positioning micrometer.…”

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confidence: 99%

“…If zð0Þ and C cl are known, but the evaporation ignored, the contact angle of an equivalently sized equilibrium droplet e may be determined by the methods described in [19]. The values of e correlate with , but are always less, Table I. The pressures in the liquid and vapor phases at the interface were obtained as part of the procedure to predict the droplet shape, and the temperatures in each phase at 10 points along the interface were measured.…”

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confidence: 99%

Energy Transport by Thermocapillary Convection during Sessile-Water-Droplet Evaporation

2010

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The energy transport mechanisms of a sessile-water droplet evaporating steadily while maintained on a Cu substrate are compared. Buoyancy-driven convection is eliminated, but thermal conduction and thermocapillary convection are active. The dominant mode varies along the interface. Although neglected in previous studies, near the three-phase line, thermocapillary convection is by far the larger mode of energy transport, and this is the region where most of the droplet evaporation occurs.

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Sessile-Water-Droplet Contact Angle Dependence on Adsorption at the Solid−Liquid Interface

Cited by 38 publications

References 38 publications

Atomic Force Microscope‐Based Meniscus‐Confined Three‐Dimensional Electrodeposition

Atomic Force Microscope‐Based Meniscus‐Confined Three‐Dimensional Electrodeposition

Protein adsorption in three dimensions

Energy Transport by Thermocapillary Convection during Sessile-Water-Droplet Evaporation

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