Capillary Torque on a Particle Rotating at an Interface

Naga, Abhinav; Vollmer, Doris; Butt, Hans‐Jürgen

doi:10.1021/acs.langmuir.1c00851

Cited by 10 publications

(11 citation statements)

References 42 publications

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“…Because rotation causes a decrease in the detachment force, it may, at first, seem that inducing the rotation of particles could be a useful way to facilitate the detachment of particles from interfaces. However, this may not be economical from an energetic perspective because in order to rotate a particle against an interface, energy needs to be supplied to overcome resistive capillary torque (described in ref 19). Capillary torque is due to the fact that the liquid−fluid interface is not axisymmetric about the center of a rotating particle.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…23−28 On one side of the rotational axis, the particle rolls out of the liquid, and therefore, the contact angle corresponds to the receding contact angle, whereas on the opposite side the contact angle corresponds to the advancing contact angle, Θ A . 19 In general, Θ A differs from Θ R due to chemical and topographical inhomogeneities on the particle and/or adaptation of the particle to the liquid. 29,30 Consequently, eq 1 does not hold for a rotating particle and should be modified.…”

Section: ■ Introductionmentioning

confidence: 99%

“…For example, it has been shown that the contact angle around spherical and prismatic particles varies along their three-phase contact line − and that the contact angle around a Janus particle varies around the contact line when the particle is oriented such that the boundary between the lyophobic and lyophilic hemispheres lies at a finite angle to an interface . Another example where the contact angle does not take a single value is when a particle rotates against a liquid–fluid interface, as shown in Figure a . There are several instances when rotation against an interface may become relevant: when a particle rolls down a wet or lubricated substrate, , when a water drop removes contaminant particles from a substrate, when strong winds blow on soil or dust particles at the surface of a lake or river, and when a particle with an electric or magnetic dipole moment is placed at an interface in an electric or magnetic field, respectively. − On one side of the rotational axis, the particle rolls out of the liquid, and therefore, the contact angle corresponds to the receding contact angle, whereas on the opposite side the contact angle corresponds to the advancing contact angle, Θ A .…”

Section: Introductionmentioning

confidence: 99%

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The Force Required to Detach a Rotating Particle from a Liquid–Fluid Interface

2021

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The force required to detach a particle from a liquid–fluid interface is a direct measure of the capillary adhesion between the particle and the interface. Analytical expressions for the detachment force are available but are limited to nonrotating particles. In this work, we derive analytical expressions for the force required to detach a rotating spherical particle from a liquid–fluid interface. Our theory predicts that the rotation reduces the detachment force when there is a finite contact angle hysteresis between the particle and the liquid. For example, the force required to detach a particle with an advancing contact angle of 120° and a receding contact angle of 80° (e.g., polydimethylsiloxane particle at a water–air interface) is expected to be 25% lower when the particle rotates while it is detached.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The Force Required to Detach a Rotating Particle from a Liquid–Fluid Interface

2021

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“…Contact dynamic effects, such as contact angle hysteresis or contact line pinning, are certainly important when capillary bonds are stretched or compressed but can also arise under rotation, as shown in Figure 5 [60]. Naga et al recently showed that a particle situated at an interface between two phases can experience similar effects as a liquid droplet sliding across a surface or a sphere rotating above a surface.…”

Section: Nonideal Wettingmentioning

confidence: 99%

The behavior of capillary suspensions at diverse length scales: From single capillary bridges to bulk

Bindgen¹,

Allard²,

Koos

2022

Current Opinion in Colloid & Interface Science

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Liquid-liquid-solid systems are becoming increasingly common in everyday life with many possible applications. Here, we focus on a special case of such liquid-liquid-solid systems, namely, capillary suspensions. These capillary suspensions originate from particles that form a network based on capillary forces and are typically composed of solids in a bulk liquid with an added secondary liquid. The structure of particle networks based on capillary bridges possesses unique properties compared with networks formed via other attractive interactions where these differences are inherently related to the properties of the capillary bridges, such as bridge breaking and coalescence between adjacent bridges. Thus, to tailor the mechanical properties of capillary suspensions to specific requirements, it is important to understand the influences on different length scales ranging from the dynamics of the bridges with varying external stimuli to the often heterogeneous network structure.

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“…Contact dynamical effects, such as contact angle hysteresis or contact line pinning, are certainly important when capillary bonds are stretched or compressed, but can also arise under rotation, as shown in Figure 5. [57] Naga et al recently showed that a particle situated at an interface between two phases can experience similar effects as a liquid droplet sliding across a surface or a sphere rotating above a surface. The resulting force or torque forms a barrier similar to an activation energy that needs to be overcome in order to reach a state of unhindered sliding or rotation.…”

Section: Non-ideal Wettingmentioning

confidence: 99%

The behavior of capillary suspensions at diverse length scales: from single capillary bridges to bulk

Bindgen,

Allard,

Koos

2021

Preprint

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Liquid-liquid-solid systems are becoming increasingly common in everyday life with many possible applications. Here, we focus on a special case of such liquid-liquid-solid systems, namely capillary suspensions. These capillary suspensions originate from particles that form a network based on capillary forces and are typically composed of a solids in a bulk liquid with an added secondary liquid. The structure of particle networks based on capillary bridges posses unique properties compared to networks formed via other attractive interactions where these differences are inherently related to the properties of the capillary bridges, such as bridge breaking and coalescence between adjacent bridges. Thus, to tailor the mechanical properties of capillary suspensions to specific requirements, it is important to understand the influences on different length scales ranging from the dynamics of the bridges with varying external stimuli to the often heterogeneous network structure.

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Capillary Torque on a Particle Rotating at an Interface

Cited by 10 publications

References 42 publications

The Force Required to Detach a Rotating Particle from a Liquid–Fluid Interface

The Force Required to Detach a Rotating Particle from a Liquid–Fluid Interface

The behavior of capillary suspensions at diverse length scales: From single capillary bridges to bulk

The behavior of capillary suspensions at diverse length scales: from single capillary bridges to bulk

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