Square ice in graphene nanocapillaries

Algara‐Siller, Gerardo; Lehtinen, Ossi; Wang, FengChao; Nair, R. R.; Kaiser, Ute; Wu, HengAn; Geǐm, A. K.; Grigorieva, I. V.

doi:10.1038/nature14295

Cited by 670 publications

(858 citation statements)

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“…In the current simulations also, after the start of Np y T equilibration at 298 K and 1 atm, the confined region between the two MoS 2 sheets becomes completely filled with water molecules in less than 200 ps if the S-to-S interlayer distance of the Interestingly, the density profiles of water for d = 6 and 8 Å are similar to those observed in graphene confined water 30 , suggesting the similar H-bond configurations of water regardless of material difference. However, the key disparity is that, for a given interlayer distance of MoS 2 sheets, clearly separated single, double, triple, and quadruple layers are seen at ambient 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 10 conditions; whereas for graphene, a large lateral pressure is needed not just to bring water to the graphitic confinement but also to obtain a flat configuration.…”

Section: Resultssupporting

confidence: 53%

“…[16][17][18][19][20][21][22][23][24][25][26][27][28][29] Although the structures of confined water have been predicted for a variety of dimensions and materials using molecular dynamics (MD) simulations, the first experimental observation of the 2D water in between the two graphene sheets was obtained very recently using high-resolution transmission electron microscopy measurements (TEM). 30 This observation revealed the formation of a monolayer of planar "square" ice with a high packing density and, depending on the inter-graphene distance, the formation of bi-and trilayer crystallites of water. 30 The same authors have also reported the MD simulations of graphene-confined water that agreed with the experimental structure of the "square ice".…”

Section: Introductionmentioning

confidence: 99%

“…30 This observation revealed the formation of a monolayer of planar "square" ice with a high packing density and, depending on the inter-graphene distance, the formation of bi-and trilayer crystallites of water. 30 The same authors have also reported the MD simulations of graphene-confined water that agreed with the experimental structure of the "square ice". However this involved an enormous lateral van der Waals pressure of about 1 GPa (10,000 atm) to obtain a flat structure of water for the bilayer and trilayer distances.…”

Section: Introductionmentioning

confidence: 99%

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Multilayer Two-Dimensional Water Structure Confined in MoS₂

et al. 2017

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The conflicting interpretations (square vs. rhomboidal) of the recent experimental visualization of the two-dimensional (2D) water confined in between two graphene sheets by transmission electron microscopy measurements, make it important to clarify how the structure of twodimensional water depends on the constraining medium. Toward the end, we report here molecular dynamics (MD) simulations to characterize the structure of water confined in between two MoS 2 sheets. Unlike graphene, water spontaneously fills the region sandwiched by two MoS 2 sheets in ambient conditions to form planar multi-layered water structures with up to four layer. These 2D water molecules form a specific pattern in which the square ring structure is formed by four diamonds via H-bonds, while each diamond shares a corner in a perpendicular manner, yielding an intriguing isogonal tiling structure. Comparison of the water structure confined in graphene (flat uncharged surface) vs. MoS 2 (ratchet-profiled charged surface) demonstrates that the polarity (charges) of the surface can tailor the density of confined water, which in turn can directly determine the planar ordering of the multi-layered water molecules in graphene or MoS 2 . On the other hand, the intrinsic surface profile (flat vs. ratchet-profiled) plays a minor role in determining the 2D water configuration.

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Section: Resultssupporting

confidence: 53%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Multilayer Two-Dimensional Water Structure Confined in MoS₂

et al. 2017

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“…Thus, the interaction between Gr and CO is in the repulsion regime, and CO adsorption is destabilized in the confined space. It has been recently demonstrated that vdW forces between 2D materials can be so strong on a nanometer scale that huge pressure up to 1 GPa is built therein (40,41). Therefore, we conclude that the vdW interaction between the opposite walls of the 2D microenvironment has induced strong geometric constraint on trapped interlayer molecules, which contributes to the confinement effect.…”

Section: Resultsmentioning

confidence: 86%

Confined catalysis under two-dimensional materials

Xiao

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

228

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Confined microenvironments formed in heterogeneous catalysts have recently been recognized as equally important as catalytically active sites. Understanding the fundamentals of confined catalysis has become an important topic in heterogeneous catalysis. Well-defined 2D space between a catalyst surface and a 2D material overlayer provides an ideal microenvironment to explore the confined catalysis experimentally and theoretically. Using density functional theory calculations, we reveal that adsorption of atoms and molecules on a Pt(111) surface always has been weakened under monolayer graphene, which is attributed to the geometric constraint and confinement field in the 2D space between the graphene overlayer and the Pt(111) surface. A similar result has been found on Pt(110) and Pt(100) surfaces covered with graphene. The microenvironment created by coating a catalyst surface with 2D material overlayer can be used to modulate surface reactivity, which has been illustrated by optimizing oxygen reduction reaction activity on Pt(111) covered by various 2D materials. We demonstrate a concept of confined catalysis under 2D cover based on a weak van der Waals interaction between 2D material overlayers and underlying catalyst surfaces.confined catalysis | two-dimensional materials | density functional theory | oxygen reduction reaction | graphene I n heterogeneous catalysis, active sites have long been regarded as one of the most important concepts (1-3), and, recently, the heterogeneous catalysis community has started to recognize that microenvironment around the active site is equally important (4-9). The confined microenvironment on a heterogeneous catalyst can help to stabilize active sites and modulate chemistry at the sites, which has a significant effect on catalytic performance, similar to the role of spheroproteins in an enzyme (10). Hence, understanding fundamentals of confined catalysis has become an important topic in heterogeneous catalysis (11,12).Reactions in zero-dimensional (0D) nanocavities of microporous and mesoporous materials such as zeolites and metal−organic frameworks (MOFs) have shown enhanced catalytic performance (6,9,(13)(14)(15). Theoretical investigations reveal that the spatially confined environment increases the molecular orbital energy and changes activity of the confined molecules, which have been recognized as the nest effect and quantum confinement effect (15, 16). In past decades, some experimental studies have demonstrated that carbon nanotubes (CNTs) strongly affect catalytic reactions occurring inside the nanotubes (7,17,18), and confined catalysis in 1D nanocavities has been theoretically addressed by studying molecule adsorption on metal clusters encapsulated in CNTs (19). As illustrated in Fig. 1, both 0D nanocavities in zeolites and 1D nanocavities in CNTs are spatially confined in three dimensions and two dimensions, respectively, in which simple and well-defined model systems are not feasible for both theoretical and experimental studies. Moreover, structural and composit...

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“…The repulsion presented in this Letter, which is missing from classical force fields and density functional approximations, would introduce an intermolecular repulsion, which may rationalize a higher flow rate with increasing confinement. The 2D oscillator dimer example is related to a recent experiment [52] where a previously unknown ice structure has been discovered when water molecules are encapsulated between two graphene sheets, thereby suggesting peculiar intermolecular interaction between water molecules under quasi-2D confinement. In fact, a recent quantum Monte Carlo study [53] of stable square ice between graphene sheets shows that most dispersion-corrected DFT functionals overestimate the binding in the water layer.…”

Section: Prl 118 210402 (2017) P H Y S I C a L R E V I E W L E T T Ementioning

confidence: 99%

Long-Range Repulsion Between Spatially Confined van der Waals Dimers

Sadhukhan

Tkatchenko

2017

Phys. Rev. Lett.

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It is an undisputed textbook fact that nonretarded van der Waals (vdW) interactions between isotropic dimers are attractive, regardless of the polarizability of the interacting systems or spatial dimensionality. The universality of vdW attraction is attributed to the dipolar coupling between fluctuating electron charge densities. Here, we demonstrate that the long-range interaction between spatially confined vdW dimers becomes repulsive when accounting for the full Coulomb interaction between charge fluctuations. Our analytic results are obtained by using the Coulomb potential as a perturbation over dipole-correlated states for two quantum harmonic oscillators embedded in spaces with reduced dimensionality; however, the longrange repulsion is expected to be a general phenomenon for spatially confined quantum systems. We suggest optical experiments to test our predictions, analyze their relevance in the context of intermolecular interactions in nanoscale environments, and rationalize the recent observation of anomalously strong screening of the lateral vdW interactions between aromatic hydrocarbons adsorbed on metal surfaces. DOI: 10.1103/PhysRevLett.118.210402 Interactions induced by quantum-mechanical charge density fluctuations, such as van der Waals (vdW) and Casimir forces, are always present between objects with finite dimensions [1][2][3][4]. Such interactions are important not only for many fundamental phenomena throughout the fields of biology, chemistry, and physics but also for the design and performance of micro-and nano-structured devices. While Casimir forces can be both attractive or repulsive, depending on the nature of the fluctuations (quantum and/or thermal) and the spatial structure (topology and/or geometry) of the interacting systems [5][6][7][8], it is undisputed common wisdom that nonretarded vdW interactions between two objects in vacuo are inherently attractive [9][10][11]. The universality of vdW attraction is attributed to the ubiquitous zero-point energy lowering, induced by dipolar coupling between fluctuating electron charge densities [9,10].However, many biological, chemical, and physical phenomena of importance in materials happen in spatially confined environments, as opposed to isotropic and homogeneous vacuum. The confinement can be artificially engineered by applying static or dynamic electromagnetic fields or arise as a result of the encapsulation of molecules in nanotubes, fullerenes, and/or by adsorption on polarizable surfaces. Moreover, in biological systems, proteins are typically confined in an inhomogeneous environment. We remark that even when such confinement entails tiny modification of the electron density (having no apparent effect on the electrostatics), it can visibly affect the interactions stemming from density fluctuations due to their long-range inhomogeneous nature.Here, we demonstrate that the breaking of rotational and/or translational symmetry of 3D vacuum results in repulsive long-range interactions for vdW dimers.The repulsive interaction stems from...

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Square ice in graphene nanocapillaries

Cited by 670 publications

References 48 publications

Multilayer Two-Dimensional Water Structure Confined in MoS₂

Multilayer Two-Dimensional Water Structure Confined in MoS₂

Confined catalysis under two-dimensional materials

Long-Range Repulsion Between Spatially Confined van der Waals Dimers

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Square ice in graphene nanocapillaries

Cited by 670 publications

References 48 publications

Multilayer Two-Dimensional Water Structure Confined in MoS2

Multilayer Two-Dimensional Water Structure Confined in MoS2

Confined catalysis under two-dimensional materials

Long-Range Repulsion Between Spatially Confined van der Waals Dimers

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Multilayer Two-Dimensional Water Structure Confined in MoS₂

Multilayer Two-Dimensional Water Structure Confined in MoS₂