Measuring Surface Tensions of Soft Solids with Huge Contact-Angle Hysteresis

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Measuring Surface Tensions of Soft Solids with Huge Contact-Angle Hysteresis

Jin Young Kim, Stefanie Heyden, Dominic Gerber, Nicolas Bain, Eric R. Dufresne, and Robert W. Style

Phys. Rev. X 11, 031004 – Published 7 July 2021

An article within the collection: Highlights in Experimental Statistical, Biological, and Soft-Matter Physics

Abstract

The equilibrium contact angle of a droplet resting on a solid substrate can reveal essential properties of the solid’s surface. However, when the motion of a droplet on a surface shows significant hysteresis, it is generally accepted that the solid’s equilibrium properties cannot be determined. Here, we describe a method to measure surface tensions of soft solids with strong wetting hysteresis. With independent knowledge of the surface tension of the wetting fluid and the linear-elastic response of the solid, the solid deformations under the contact line and the contact angle of a single droplet together reveal the difference in surface tension of the solid against the liquid and vapor phases If the solid’s elastic properties are unknown, then this surface tension difference can be determined from the change in substrate deformations with contact angle. These results reveal an alternate equilibrium contact angle, equivalent to the classic form of Young-Dupré, but with surface tensions in place of surface energies. We motivate and apply this approach with experiments on gelatin, a common hydrogel.

Received 8 March 2021
Revised 20 April 2021
Accepted 19 May 2021

DOI:https://doi.org/10.1103/PhysRevX.11.031004

Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article’s title, journal citation, and DOI.

Published by the American Physical Society

Physics Subject Headings (PhySH)

Capillary interactions Drops & bubbles Elastic deformation Elastic forces Surface & interfacial phenomena Surface tension effects Wetting

Fluid DynamicsPolymers & Soft Matter

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Highlights in Experimental Statistical, Biological, and Soft-Matter Physics

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Authors & Affiliations

Jin Young Kim , Stefanie Heyden, Dominic Gerber , Nicolas Bain, Eric R. Dufresne , and Robert W. Style ^*

Department of Materials, ETH Zürich 8093, Switzerland

^*robert.style@mat.ethz.ch

Popular Summary

Surface properties of solids are most commonly measured by placing a droplet on the solid and measuring the angle at which the droplet surface contacts the solid surface. This contact angle can reveal the key value that controls surface properties: the surface energy. The technique is widely applied in both science and industry and works well for rough measurements, but it can cause huge measurement uncertainty on most surfaces. Here, we showcase a novel technique that overcomes this age-old problem to accurately measure the surface properties of soft solids with wetting experiments.

Much of the uncertainty in droplet-based measurements comes from contact-angle hysteresis—various surface properties and droplet behaviors cause the value of the angle to lag behind changes to the experimental setup. Our workaround involves measuring tiny deformations of the solid directly under the contact line of the droplet and relating these to the forces acting at the surface of the solid. Essentially, this is achieved by measuring the angle at which the surface tension forces in the droplet are in horizontal force balance. While this requires knowledge of the droplet surface tension, the properties of the underlying surface can be unknown. We demonstrate this approach with droplets on gelatin surfaces.

Our technique enables the measurement of surface-tension differences and “depinning forces” on soft solids, even in the presence of huge contact-angle hysteresis. This approach should be broadly applicable in measuring surface properties of soft materials.

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Vol. 11, Iss. 3 — July - September 2021

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Images

Figure 1
Sessile glycerol-water droplets on gelatin gels swollen with the same liquid. A droplet is deposited on gelatin, where its contact line pins so that liquid can be removed without moving the contact line. (a)–(c) Side views of contact lines with different contact angles (90°, 66°, 27°, respectively) imaged with macro photography (inset) and confocal microscopy, where red (green) nanoparticles label the droplets (gelatin), respectively. (d)–(f) Enlargement of the wetting ridges in (a)–(c), rotated so that the liquid-vapor interface is vertical. Panels (g)–(i) show the displacements under the ridge, calculated by tracking nanoparticle displacements between a relaxed state where the surface is flooded with liquid and the deformed state under a contact line. The arrow colors indicate their magnitude.
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Figure 2
A schematic diagram showing the forces acting on the gelatin. (a) Near the contact line, there is a highly deformed wetting ridge. The gelatin may also be deformed by a pore pressure $P$ that acts to swell or deswell the gelatin. (b) At a scale much bigger than that of the wetting ridge, the surface forces and pore pressure effectively act as horizontal and vertical line forces at the contact line, and as a uniform compressive pressure on the surface of a flat film.
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Figure 3
Decomposing the horizontal displacements under a contact line. The top (bottom) rows show the odd (even) parts of $u_{x} (x, z)$ : $u_{x}^{o}$ and $u_{x}^{e}$ . The first three columns (a)–(c),(e)–(g) correspond to $θ = 90 °$ , 66°, 27°, respectively. The final column (d),(h) shows $U_{⊥}$ and $U_{∥}$ from Eq. (4), using $ν = 0.39$ and $h = 147 μ m$ . The experiments show good agreement with the theory. Note that the magnitude of (g) is negative, causing the colors to be the reverse of those in (e), (f), and (h).
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Figure 4
Measuring surface tensions on the gel. Panels (a) and (b) show $ϒ_{⊥} (θ)$ and $ϒ_{∥} (θ)$ , measured by fitting displacement fields to the theoretical expressions in Eqs. (4) and (5). The dashed line shows the theoretical predictions from Eqs. (2) and (3). Panel (c) shows $M$ , the relative magnitudes of the displacement fields in Figs. 3. The angle $θ_{0}$ , where $M = 0$ , corresponds to the point where the stresses acting at the gel’s surface balance horizontally. (d) The surface tension of a curing gelatin droplet, measured via pendant-droplet tensiometry. The red curve shows an exponential fit to the data, which plateaus to a value of 51 mN/m.
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Figure 5
The depinning force at the contact line at the advancing contact angle. This opposes the surface-tension forces from $ϒ_{l v}$ , $ϒ_{s v}$ , and $ϒ_{s l}$ . Note that, in general, this is not parallel to the liquid surface at the contact line.
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