Freezing of Water Confined at the Nanoscale

Alabarse, Frederico; Haines, J.; Cambon, O.; Levelut, Claire; Bourgogne, David; Haidoux, A.; Granier, Dominique; Coasne, Benoît

doi:10.1103/physrevlett.109.035701

Cited by 132 publications

(202 citation statements)

References 23 publications

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“…Crystallization, if present, would be observed as an abrupt change in I(T ), which is not seen here at any Q. This suggests that the adsorbed water does not solidify and remains mobile down to at least 150 K, consistent with previous studies [29]. It is worth noting however that the temperature range ( K) at which the water dynamics were subsequently simulated and measured, was always above the melting point of water [30,31].…”

Section: B Elastic Incoherent Scatteringsupporting

confidence: 58%

Translational diffusion of water inside hydrophobic carbon micropores studied by neutron spectroscopy and molecular dynamics simulation

et al. 2015

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When water molecules are confined to nanoscale spacings, such as in the nanometer size pores of activated carbon fiber (ACF), their freezing point gets suppressed down to very low temperatures (∼ 150 K), leading to a metastable liquid state with remarkable physical properties. We have investigated the ambient pressure diffusive dynamics of water in microporous Kynol TM ACF-10 (average pore size ∼11.6Å, with primarily slit-like pores) from temperature T = 280 K in its stable liquid state down to T = 230 K into the metastable supercooled phase. The observed characteristic relaxation times and diffusion coefficients are found to be respectively higher and lower than those in bulk water, indicating a slowing down of the water mobility with decreasing temperature. The observed temperature-dependent average relaxation time τ when compared to previous findings indicate that it is the width of the slit pores -not their curvature -that primarily affects the dynamics of water for pore sizes larger than 10Å. The experimental observations are compared to complementary molecular dynamics simulations of a model system, in which we studied the diffusion of water within the 11.6Å gap of two parallel graphene sheets. We find generally a reasonable agreement between the observed and calculated relaxation times at the low momentum transfer Q (Q ≤ 0.9Å −1 ). At high Q however, where localized dynamics becomes relevant, this ideal system does not satisfactorily reproduce the measurements. Consequently, the simulations are compared to the experiments at low Q, where the two can be best reconciled. The best agreement is obtained for the diffusion parameter D associated with the hydrogen-site when a representative stretched exponential function, rather than the standard bi-modal exponential model, is used to parameterize the self-correlation function I(Q, t) .

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Section: B Elastic Incoherent Scatteringsupporting

confidence: 58%

Translational diffusion of water inside hydrophobic carbon micropores studied by neutron spectroscopy and molecular dynamics simulation

et al. 2015

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“…[4] In other systems, water activation results in elimination of atomic or molecular hydrogen and oxidation of the metal to the metal hydroxide. [6][7][8][9][10][11][12][13][14] Ion-molecule reactions provide insight into the subtle chemistry of these species.…”

Section: Introductionmentioning

confidence: 99%

“…[1] Exchange experiments with D 2 O [2] indicate that hydrated alkali-metal ions [3] as well as most transition-metal ions M + (H 2 O) n , M= Cr, Fe, Co, Ni, Cu, and Zn, [4] consist of a singly charged metal center embedded in a hydrogenbonded network of intact H 2 O molecules, whereas room-temperature black-body infrared radiative dissociation (BIRD) [5] activates an insertion reaction in Mn + (H 2 O) n , which for n % 8-20 are converted into HMnOH + (H 2 O) nÀ1 . [4] In other systems, water activation results in elimination of atomic or molecular hydrogen and oxidation of the metal to the metal hydroxide.…”

Section: Introductionmentioning

confidence: 99%

Reduction of Acetonitrile by Hydrated Magnesium Cations Mg⁺(H₂O)_n (n≈20–60) in the Gas Phase

et al. 2013

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Ion–molecule reactions of Mg+(H2O)n (n≈20–60) with CH3CN are studied by Fourier‐transform ion‐cyclotron resonance mass spectrometry. Collision with CH3CN initiates the formation of MgOH+(H2O)n−1 together with CH3CHN. or CH3CNH., which is similar to the reaction of hydrated electrons (H2O)n− with CH3CN. In subsequent reaction steps, three more CH3CN molecules are taken up by the clusters, to form MgOH+(CH3CN)3 after a reaction delay of 60 seconds. Density functional theory (DFT) calculations at the M06/6‐31++G(d,p) level of theory suggest that the bending motion of CH3CN allows the unpaired electron that is solvated out from the Mg center to localize in a π*(CN)‐like orbital of the bent CH3CN.−, which undergoes spontaneous proton transfer to form CH3CNH. or CH3CHN., with the former being kinetically more favorable. The reaction energy for a cluster with the hexacoordinated Mg center is more exothermic than that with the pentacoordinated Mg. The CH3CNH. or CH3CHN. is preferentially solvated on the cluster surface rather than at the first solvation shell of the Mg center. By contrast, the three additional CH3CN molecules taken up by the resulting MgOH+(H2O)n clusters coordinate directly to the first solvation shell of the MgOH+ core, as revealed by DFT calculations.

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“…The air gap between the water and the hydrophobic substrate [16] makes the contacting skin more like free. However, water confined in hydrophilic nanopores [50,51] or wetting with hydrophilic topologic configurations [52] exhibits supercooling effect, or melts at lower temperature than usual because of the lacking of broken bonds.…”

Section: Further Evidencementioning

confidence: 97%

Skin Supersolidity of Water and Ice

Sun

2014

Springer Series in Chemical Physics

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• The skins of water ice share the same nature of supersolidity, which is elastic, hydrophobic, polarized, highly thermal stable, slippery.• The skin density reaches 0.75 g cm -3 , lower than that for ice 0.92 g cm -3 or liquid B1.0 g cm -3 ; the x H is 3,450 cm -1 , higher than the value of 3,200 cmfor the bulk water or the value of 3,150 cm -1 for bulk ice.• H-O bond contraction and the associated bonding electron entrapment and the dual processes of polarization create the supersolidity.

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Freezing of Water Confined at the Nanoscale

Cited by 132 publications

References 23 publications

Translational diffusion of water inside hydrophobic carbon micropores studied by neutron spectroscopy and molecular dynamics simulation

Translational diffusion of water inside hydrophobic carbon micropores studied by neutron spectroscopy and molecular dynamics simulation

Reduction of Acetonitrile by Hydrated Magnesium Cations Mg⁺(H₂O)_n (n≈20–60) in the Gas Phase

Skin Supersolidity of Water and Ice

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Freezing of Water Confined at the Nanoscale

Cited by 132 publications

References 23 publications

Translational diffusion of water inside hydrophobic carbon micropores studied by neutron spectroscopy and molecular dynamics simulation

Translational diffusion of water inside hydrophobic carbon micropores studied by neutron spectroscopy and molecular dynamics simulation

Reduction of Acetonitrile by Hydrated Magnesium Cations Mg+(H2O)n (n≈20–60) in the Gas Phase

Skin Supersolidity of Water and Ice

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Product

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Reduction of Acetonitrile by Hydrated Magnesium Cations Mg⁺(H₂O)_n (n≈20–60) in the Gas Phase