A comparison between liquid drops and solid particles in partial wetting

Stocco, Antonio; Nobili, Maurizio

doi:10.1016/j.cis.2017.06.014

Cited by 24 publications

(25 citation statements)

References 103 publications

(146 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A solid colloidal particle at a fluid interface in a partial wetting state is usually trapped in a surface energy well [46] [47]. The order of magnitude of the energy well can be roughly estimated by the surface energy of the portion of the fluid interface occupied by the particle: = 2 (for a spherical particle with a 90° wetting contact angle , see figure 3), where is the fluid interfacial tension and the particle radius.…”

Section: Motion Of Partially Wetted Colloidal Particles At a Fluid Inmentioning

confidence: 99%

Motion of micro- and nano- particles interacting with a fluid interface

Villa

Boniello

Stocco

et al. 2020

Advances in Colloid and Interface Science

Self Cite

View full text Add to dashboard Cite

In this article, we review both theoretical models and experimental results on the motion of micro-and nanoparticles that are close to a fluid interface or move in between two fluids. Viscous drags together with dissipations due to fluctuations of the fluid interface and its physicochemical properties affect strongly the translational and rotational drags of colloidal particles, which are subjected to Brownian motion in thermal equilibrium. Even if many theoretical and experimental investigations have been carried out, additional scientific efforts in hydrodynamics, statistical physics, wetting and colloid science are still needed to explain unexpected experimental results and to measure particle motion in time and space scales, which are not accessible so far.

show abstract

Section: Motion Of Partially Wetted Colloidal Particles At a Fluid Inmentioning

confidence: 99%

Motion of micro- and nano- particles interacting with a fluid interface

Villa

Boniello

Stocco

et al. 2020

Advances in Colloid and Interface Science

Self Cite

View full text Add to dashboard Cite

show abstract

“…A solid particle straddling an interface should not be simply seen as a geometrical object partially immersed in a liquid but rather as an intriguing partial wetting configuration. For colloidal microparticles, the fluid interface deformation due to gravity or other external fields is usually weak and the solid particle immersion is set by an equilibrium contact angle in analogy with the partial wetting of a sessile drop on a solid substrate [1]. This configuration, however, should not be considered static since both the colloidal particle and the contact line are subjected to thermal agitation, which results in the particle Brownian motion and in the displacement of contact line back and forth around some equilibrium position [2].…”

Section: Introductionmentioning

confidence: 99%

Rotational diffusion of partially wetted colloids at fluid interfaces

Stocco

Chollet

Wang

et al. 2019

Journal of Colloid and Interface Science

Self Cite

View full text Add to dashboard Cite

Hypothesis Rotational Brownian diffusions of colloidal particles at a fluid interface play important roles in particle self-assembly and in surface microrheology. Recent experiments on translational Brownian motion of spherical particles at the air-water interface show a significant slowing down of the translational diffusion with respect to the hydrodynamic predictions [Boniello et al. Nat. Mat. 14 (2015) 908-11]. For the rotational diffusions of partially wetted colloids, slowing down of the particle dynamics can be also expected. Experiments Here, the rotational dynamics of Janus colloids at the air-water interface have been experimentally investigated using optical microscopy. Bright field and fluorescent microscopies have been used to measure the in-plane and out-of-plane particle rotational diffusions exploiting the Janus geometry of the colloids we fabricated. Findings Our results show a severe slowing down of the rotational diffusion Dr, connected to the contact line motion and wetting-dewetting dynamics occurring on particle regions located at opposite liquid wedges. A slowing down of the particle rotational diffusion about an axis parallel to the interfacial normal Dr,|| was also observed. Contact line fluctuations due to partial wetting dynamics lead to a rotational line friction that we have modelled in order to describe our results.

show abstract

“…The former is expressed as the capillary length ((l c =@γ Δρg ⁄ ), where γ is the surface/interfacial tension, Δρ the liquid density difference and g the gravitational acceleration), which is around 2.71 mm in air/water and 4.44 mm for decane/water, while the latter operates below a characteristic length scale l s =θ E -2 @H 6πγ ⁄ ≈ 1-10 nm, θE is the ECA, and H is the Hamaker constant. If the principal radii are smaller than lc, gravitational forces do not influence the shape of the droplet or interface for sessile droplets or adsorbing colloids, respectively [84]. The sessile drops in this study on the substrates and the NP size are well below lc and above ls.…”

Section: Comparing Contact Angles At the Nano-and Macroscalementioning

confidence: 65%