Interface-Induced Ordering of Gas Molecules Confined in a Small Space

Lu, Yuhui; Yang, Chih‐Wen; Fang, Chung‐Kai; Ko, Hsien-Chen; Hwang, Ing−Shouh

doi:10.1038/srep07189

Cited by 61 publications

(90 citation statements)

References 49 publications

(117 reference statements)

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“…We note that the row-like structures reported here bear some resemblance with recent reports of longitudinal nanobubbles forming at the surface of HOPG in pure water, allegedly from dissolved gas molecules 26 27 . Nanobubbles can be excluded here considering the scale of the smallest features observed.…”

Section: Discussionsupporting

confidence: 87%

Thermally-nucleated self-assembly of water and alcohol into stable structures at hydrophobic interfaces

et al. 2016

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At the interface with solids, the mobility of liquid molecules tends to be reduced compared with bulk, often resulting in increased local order due to interactions with the surface of the solid. At room temperature, liquids such as water and methanol can form solvation structures, but the molecules remain highly mobile, thus preventing the formation of long-lived supramolecular assemblies. Here we show that mixtures of water with methanol can form a novel type of interfaces with hydrophobic solids. Combining in situ atomic force microscopy and multiscale molecular dynamics simulations, we identify solid-like two-dimensional interfacial structures that nucleate thermally, and are held together by an extended network of hydrogen bonds. On graphite, nucleation occurs above ∼35 °C, resulting in robust, multilayered nanoscopic patterns. Our findings could have an impact on many fields where water-alcohol mixtures play an important role such as fuel cells, chemical synthesis, self-assembly, catalysis and surface treatments.

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Section: Discussionsupporting

confidence: 87%

Thermally-nucleated self-assembly of water and alcohol into stable structures at hydrophobic interfaces

et al. 2016

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“…45,46 Similarly, the adsorption of contamination by (allegedly) 5 condensed gas is either not present or indiscriminate. 32 These data are in line with the 6 universality of the contact angle according to the model by Zhang and Lohse that predicts a 7 universal contact angle that solely depends on the gas oversaturation. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 …”

supporting

confidence: 81%

AFM Study of Surface Nanobubbles on Binary Self-Assembled Monolayers on Ultraflat Gold with Identical Macroscopic Static Water Contact Angles and Different Terminal Functional Groups

et al. 2016

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All experimental findings related to surface nanobubbles, such as their pronounced stability and the striking differences of macroscopic and apparent nanoscopic contact angles, need to be addressed in any theory or model of surface nanobubbles. In this work we critically test a recent explanation of surface nanobubble stability and their consequences and contrast this with previously proposed models. In particular, we elucidated the effect of surface chemical composition of well-controlled solid-aqueous interfaces of identical roughness and defect density on the apparent nanoscopic contact angles. Expanding on a previous atomic force microscopy (AFM) study on the systematic variation of the macroscopic wettability using binary self-assembled monolayers (SAMs) on ultraflat template stripped gold (TSG), we assessed here the effect of different surface chemical composition for macroscopically identical static water contact angles. SAMs on TSG with a constant macroscopic water contact angle of 81 ± 2° were obtained by coadsorption of a methyl-terminated thiol and a second thiol with different terminal functional groups, including hydroxy, amino, and carboxylic acid groups. In addition, surface nanobubbles formed by entrainment of air on SAMs of a bromoisobutyrate-terminated thiol were analyzed by AFM. Despite the widely differing surface potentials and different functionality, such as hydrogen bond acceptor or donor, and different dipole moments and polarizability, the nanoscopic contact angles (measured through the condensed phase and corrected for AFM tip broadening effects) were found to be 145 ± 10° for all surfaces. Hence, different chemical functionalities at identical macroscopic static water contact angle do not noticeably influence the apparent nanoscopic contact angle of surface nanobubbles. This universal contact angle is in agreement with recent models that rely on contact line pinning and the equilibrium of gas outflux due to the Laplace pressure and gas influx due to gas oversaturation in the aqueous medium.

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“…3a) and stiffness ( Supplementary Fig. 3b) acquired with PeakForce mode, the cap-shaped nanostructures on graphene-covered regions exhibited a darker contrast in stiffness than the other regions, resembling the INBs reported elsewhere 10,11,17,18 . The force curves measured on the cap-shaped structures also exhibited 5 characteristics that were very similar to those of INBs [17][18][19] ( Supplementary Fig.…”

supporting

confidence: 71%

“…However, typical domain sizes at the HOPG-water interface are on the order of tens of nm 17,18,[20][21][22] , much smaller than those observed at the graphene-water interface, which are on the order of hundreds of nm or larger. Similar striped patterns of large domains were also reported for graphene in air 23 , and recently they were concluded to be responsible for friction anisotropy measured on graphene 24 .…”

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confidence: 99%

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High-Resolution Characterization of Preferential Gas Adsorption at the Graphene–Water Interface

Hsu

Yang

et al. 2016

Langmuir

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The contact of water with graphene is of fundamental importance and of great interest for numerous promising applications, but how graphene interacts with water remains unclear. Here we used atomic force microscopy (AFM) to investigate hydrophilic mica substrates with some regions covered by mechanically exfoliated graphene layers in water. In water containing air gas close to the saturation concentration (within ∼40%), cap-shaped nanostructures (or interfacial nanobubbles) and ordered-stripe domains were observed on graphene-covered regions but not on pure mica regions. These structures did not appear on graphene when samples were immersed in highly degassed water, indicating that their formation was caused by the adsorption of gas dissolved in water. Thus, atomically thin graphene, even at a narrow width of 20 nm, changes the local surface chemistry of a highly hydrophilic substrate. Furthermore, surface hydrophobicity significantly affects gas adsorption, which has broad implications for diverse phenomena in water.

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Interface-Induced Ordering of Gas Molecules Confined in a Small Space

Cited by 61 publications

References 49 publications

Thermally-nucleated self-assembly of water and alcohol into stable structures at hydrophobic interfaces

Thermally-nucleated self-assembly of water and alcohol into stable structures at hydrophobic interfaces

AFM Study of Surface Nanobubbles on Binary Self-Assembled Monolayers on Ultraflat Gold with Identical Macroscopic Static Water Contact Angles and Different Terminal Functional Groups

High-Resolution Characterization of Preferential Gas Adsorption at the Graphene–Water Interface

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