Evaporation and instabilities of microscopic capillary bridges

Maeda, Nobuyo; Israelachvili, Jacob N.; Kohonen, Mika M.

doi:10.1073/pnas.0234283100

Cited by 128 publications

(122 citation statements)

References 30 publications

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“…To our knowledge, no comprehensive studies on capillary bridge evaporation have been undertaken. There are a few notable exceptions of a specifically focused work on nano-scale separations (<100 nm) by Gao [11] and Maeda et al [12], or spheres at direct contact, Cutts and Burns [13], or on drying of colloidal crystals by Zhou et al [14]. Most of the previous studies on the capillary forces in two-grain liquid bridges deal with extension of the bridges at a constant liquid volume or a constant suction [12,[15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Evaporation-induced evolution of the capillary force between two grains

2014

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The evolution of capillary forces during evaporation and the corresponding changes in the geometrical characteristics of liquid (water) bridges between two glass spheres with constant separation are examined experimentally. For comparison, the liquid bridges were also tested for mechanical extension (at constant volume). The obtained results reveal substantial differences between the evolution of capillary force due to evaporation and the evolution due to extension of the liquid bridges. During both evaporation and extension, the change of interparticle capillary forces consists in a force decrease to zero either gradually or via rupture of the bridge. At small separations between the grains (short & wide bridges) during evaporation and at large volumes during extension, there is a slight initial increase of force. During evaporation, the capillary force decreases slowly at the beginning of the process and quickly at the end of the process; during extension, the capillary force decreases quickly at the beginning and slowly at the end of the process. Rupture during evaporation of the bridges occurs most abruptly for bridges with wider separations (tall and thin), sometimes occurring after only 25 % of the water volume was evaporated. The evolution (pinning/depinning) of two geometrical characteristics of the bridge, the diameter of the threephase contact line and the "apparent" contact angle at the solid/liquid/gas interface, seem to control the capillary force evolution. The findings are of relevance to the mechanics of unsaturated granular media in the final phase of drying.

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Section: Introductionmentioning

confidence: 99%

Evaporation-induced evolution of the capillary force between two grains

2014

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“…The prediction of subharmonics due to water impacts could thus be used to investigate processes such as nucleation time of water columns in the nanoscale for which a physical understanding is still emerging. 24,27,29,47,48 …”

Section: B Subharmonics and Limit Cyclesmentioning

confidence: 99%

Subharmonic excitation in amplitude modulation atomic force microscopy in the presence of adsorbed water layers

Santos¹,

Barcons

Verdaguer

et al. 2011

Journal of Applied Physics

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Dielectrophoretic assembly and atomic force microscopy modification of reduced graphene oxide J. Appl. Phys. 110, 114515 (2011) Quasi in situ scanning force microscope with an automatic operated reaction chamber Rev. Sci. Instrum. 82, 113709 (2011) Mapping of conservative and dissipative interactions in bimodal atomic force microscopy using open-loop and phase-locked-loop control of the higher eigenmode Appl. Phys. Lett. 99, 074103 (2011) Wideband phase-locked loop circuit with real-time phase correction for frequency modulation atomic force microscopy Rev. Sci. Instrum. 82, 073707 (2011) Additional information on J. Appl. Phys. In ambient conditions, nanometric water layers form on hydrophilic surfaces covering them and significantly changing their properties and characteristics. Here we report the excitation of subharmonics in amplitude modulation atomic force microscopy induced by intermittent water contacts. Our simulations show that there are several regimes of operation depending on whether there is perturbation of water layers. Single period orbitals, where subharmonics are never induced, follow only when the tip is either in permanent contact with the water layers or in pure noncontact where the water layers are never perturbed. When the water layers are perturbed subharmonic excitation increases with decreasing oscillation amplitude. We derive an analytical expression which establishes whether water perturbations compromise harmonic motion and show that the predictions are in agreement with numerical simulations. Empirical validation of our interpretation is provided by the observation of a range of values for apparent height of water layers when subharmonic excitation is predicted.

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“…A downward portion between two subsequent bundles of water chains gradually changed as the distance decreased, suggesting that the observed oscillatory forces are different from the mechanical instabilities of the Page 9 of 25 meniscus, such as pinning/unpinning of the contact line (of which the transition would be abrupt), 64 or a coupling between evaporation/condensation of vapor (which are highly unstable phenomena). 65 We also excluded the instability of the feedback loop as the origin of the observed oscillatory forces because the feedback signal is stable even with such abrupt changes in the square wave in our routine feedback optimization procedure (see Experimental Section). The oscillatory forces had amplitudes of 3-12 nN in normal force channel, and periodicities of 1.04±0.25 nm and 0.94±0.16 nm for valley-valley and for peak-peak distances, respectively.…”

Section: Page 7 Of 25mentioning

confidence: 99%

Direct observation of self-assembled chain-like water structures in a nanoscopic water meniscus

Kim

Boehm

Bonander

2013

The Journal of Chemical Physics

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Sawtooth-like oscillatory forces generated by water molecules confined between two oxidized silicon surfaces were observed using a cantilever-based optical interfacial force microscope when the two surfaces approached each other in ambient environments. The humidity-dependent oscillatory amplitude and periodicity were 3-12 nN and 3-4 water diameters, respectively. Half of each period was matched with a freely jointed chain model, possibly suggesting that the confined water behaved like a bundle of water chains. The analysis also indicated that water molecules self-assembled to form chain-like structures in a nanoscopic meniscus between two hydrophilic surfaces in air. From the friction force data measured simultaneously, the viscosity of the chain-like water was estimated to be between 10 8 and 10 10 times greater than that of bulk water. The suggested chain-like structure resolves many unexplained properties of confined water at the nanometer scale, thus dramatically improving the understanding of a variety of water systems in nature.

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Evaporation and instabilities of microscopic capillary bridges

Cited by 128 publications

References 30 publications

Evaporation-induced evolution of the capillary force between two grains

Evaporation-induced evolution of the capillary force between two grains

Subharmonic excitation in amplitude modulation atomic force microscopy in the presence of adsorbed water layers

Direct observation of self-assembled chain-like water structures in a nanoscopic water meniscus

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