Evidence for stable square ice from quantum Monte Carlo

Chen, Ji; Zen, Andrea; Brandenburg, Jan Gerit; Alfè, Dario; Michaelides, Angelos

doi:10.1103/physrevb.94.220102

Cited by 54 publications

(80 citation statements)

References 72 publications

(154 reference statements)

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“…DMC methods have also been used to predict the phase diagram of water ice trapped between two graphene sheets, finding that the hexagonal and pentagonal phases that are most stable at ambient pressure transition to a square structure at higher pressure. 208 These results are of relevance to transmission electron microscopy studies of water confined between graphene sheets. Again, the DMC results reveal inconsistencies and the need for improvement of van der Waals-inclusive DFT functionals.…”

Section: Van Der Waals Interactions At Surfaces and Between Moleculesmentioning

confidence: 77%

Variational and diffusion quantum Monte Carlo calculations with the CASINO code

Needs

Towler

Drummond

et al. 2020

The Journal of Chemical Physics

123

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Section: Van Der Waals Interactions At Surfaces and Between Moleculesmentioning

confidence: 77%

Variational and diffusion quantum Monte Carlo calculations with the CASINO code

Needs

Towler

Drummond

et al. 2020

The Journal of Chemical Physics

123

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“…horizontal bar is the statistical error in determining V 0 using measurements for several monolayer devices. Inset: Square-like ice is one of the possible ices expected inside the 2D channels at room temperature, as found from molecular dynamics analyses 18,28,29 Proton transport can be probed more directly using Nafion instead of HCl (ref. 24).…”

Section: Fig 3 Proton Transport Through Monolayer Water Inside 2d Cmentioning

confidence: 99%

Complete steric exclusion of ions and proton transport through confined monolayer water

Gopinadhan

Esfandiar

et al. 2019

Science

242

234

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Biological membranes allow permeation of water molecules but can reject even smallest ions. Behind these exquisite separation properties are protein channels with angstrom-scale constrictions (e.g., aquaporins). Despite recent progress in creating nanoscale pores and capillaries, they still remain distinctly larger than protein channels. We report capillaries made by effectively extracting one atomic plane from bulk crystals, which leaves a two-dimensional slit of a few Å in height. Water moves through these capillaries with little resistance whereas no permeation could be detected even for such small ions as Na + and Cl -. Only protons can diffuse through monolayer water inside the capillaries. The observations improve our understanding of molecular transport at the atomic scale and suggest further ways to replicate the impressive machinery of living cells.It has long been an aspirational goal to create artificial structures and devices with separation properties similar to those of biological membranes 1-5 . The latter utilize a number of separation mechanisms but it is believed that angstrom-scale constrictions within protein channels 6,7 play a key role in steric (size) exclusion of ions with the smallest hydration diameters D H  7 Å, typically present in biofluids and seawater 8,9 . Such constrictions are particularly difficult to replicate artificially because of the lack of fabrication tools capable to operate with such precision and, also, because the surface roughness of materials is typically much larger than the required angstrom scale 1 . Nonetheless, several artificial systems with nanometer and sub-nanometer dimensions were recently demonstrated, including narrow carbon and boron-nitride nanotubes 5,10,11 , graphene oxide laminates 12,13 and atomic-scale pores in graphene and MoS 2 monolayers 3,4,14 . The resulting devices exhibited high selectivity with respect to certain groups of ions (for example, they blocked large ions but allowed small ones 12,13 or rejected anions but allowed cations and vice versa 2,3,5 ). Most recently, van der Waals assembly of two-dimensional (2D) crystals 15 was used to make slit-like channels of several Å in height 16,17 . They were atomically smooth and chemically inert and exhibited little ( 10 -4 C cm -2 ) surface charge 17 . The channels allowed fast water permeation 16 and blocked large ions with a complete cutoff for diameters larger than 10 Å (ref. 17 ). Small ions (for example, those in seawater with D H of 7 Å) still permeated through those channels with little hindrance, showing that an angstrom-scale confinement comparable to that in aquaporins 6,7 is essential for steric exclusion of small-diameter ions. In this report, we describe 2D channels with the height h of about 3.4 Å (ref. 18), which are twice smaller than any hydrated ion (smallest ions are K + and Clwith D H  6.6 Å) 8,19 but sufficiently large to allow water inside (effective size of water molecules is 2.8 Å). The achieved confinement matches the size of protein constrictions in biological ...

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“…The two-dimensional ice polymorphs have been constructed in Ref. 59 by confining a single water layer resulting in four stable polymorphs of hexagonal, pentagonal, square, and rhombic ice structures. The three bulk ice phases cover the subtle balance of the competing polymorphs Ih, II and the high-pressure form VIII.…”

Section: A Systems Under Considerationmentioning

confidence: 99%

“…The reference values for the 2-dimensional ice crystals are taken from Ref. 59, while for the three bulkice crystals are given in Ref. 54.…”

Section: B Reference Interaction Energiesmentioning

confidence: 99%

Interaction between water and carbon nanostructures: How good are current density functional approximations?

Brandenburg

Zen

Michaelides

2019

The Journal of Chemical Physics

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Due to their current and future technological applications, including realisation of water filters and desalination membranes, water adsorption on graphitic sp 2 -bonded carbon is of overwhelming interest. However, these systems are notoriously challenging to model, even for electronic structure methods such as density functional theory (DFT), because of the crucial role played by London dispersion forces and non-covalent interactions in general. Recent efforts have established reference quality interactions of several carbon nanostructures interacting with water. Here, we compile a new benchmark set (dubbed WaC18), which includes a single water molecule interacting with a broad range of carbon structures, and various bulk (3D) and two dimensional (2D) ice polymorphs. The performance of 28 approaches, including semi-local exchange-correlation functionals, non-local (Fock) exchange contributions, and long-range van der Waals (vdW) treatments, are tested by computing the deviations from the reference interaction energies. The calculated mean absolute deviations on the WaC18 set depends crucially on the DFT approach, ranging from 135 meV for LDA to 12 meV for PBE0-D4. We find that modern vdW corrections to DFT significantly improve over their precursors. Within the 28 tested approaches, we identify the best performing within the functional classes of: generalized gradient approximated (GGA), meta-GGA, vdW-DF, and hybrid DF, which are BLYP-D4, TPSS-D4, rev-vdW-DF2, and PBE0-D4, respectively.

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Evidence for stable square ice from quantum Monte Carlo

Cited by 54 publications

References 72 publications

Variational and diffusion quantum Monte Carlo calculations with the CASINO code

Variational and diffusion quantum Monte Carlo calculations with the CASINO code

Complete steric exclusion of ions and proton transport through confined monolayer water

Interaction between water and carbon nanostructures: How good are current density functional approximations?

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