Helium in polygonal nanopores at zero temperature: Density functional theory calculations

2010

J Low Temp Phys

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Section: Introductionmentioning

confidence: 99%

Fluid Helium in a Narrow Pore at Zero Temperature

2010

J Low Temp Phys

“…In cases where the physical effects of such structure can be safely neglected, as for alkali-metal surfaces interacting with liquid helium, it provides a good adsorption potential for nonplanar geometries. 22 We have considered an alkali planar surface hosting a periodic array of parabolic nanocavities of height h =35 Å and outer radius R = 25 Å lying on the ͑x , y͒ plane. This geometry is inspired on substrates studied in Ref.…”

Section: Theory and Numerical Proceduresmentioning

confidence: 99%

“…14 More recently, the existence of natural and manufactured nanopores 15,16 on the one side, and, on the other, the possibility of growing surfaces structured within the nanoscale, triggered experimental and theoretical lines of research, oriented toward pore filling and wetting of nanopatterned substrates by classical fluids. [16][17][18] The condensation of helium in nanopores at zero temperature has been analyzed using variational Jastrow-Feenberg, 19 variational Monte Carlo, 20 and mean field 21,22 techniques; in particular, we have proven that finite-range density-functional ͑FRDF͒ theory is a powerful instrument in detecting multiple equilibrium states and trace hysteretic loops in the road toward capillary condensation of helium in weakly adsorbing pores. 22 On the other hand, finite temperature FRDF is also adequate in examining aspects of wetting properties of helium on Cs, such as the contact angle 23,24 and the wetting temperature of the semi-infinite metal.…”

Section: Introductionmentioning

confidence: 99%

“…[16][17][18] The condensation of helium in nanopores at zero temperature has been analyzed using variational Jastrow-Feenberg, 19 variational Monte Carlo, 20 and mean field 21,22 techniques; in particular, we have proven that finite-range density-functional ͑FRDF͒ theory is a powerful instrument in detecting multiple equilibrium states and trace hysteretic loops in the road toward capillary condensation of helium in weakly adsorbing pores. 22 On the other hand, finite temperature FRDF is also adequate in examining aspects of wetting properties of helium on Cs, such as the contact angle 23,24 and the wetting temperature of the semi-infinite metal. 25 Other applications of T-dependent density functionals in describing liquid-gas coexistence, and interfacial properties of superfluid and normal 4 He validate this approach.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Helium on planar and nanostructured alkali-metal surfaces

Ancilotto¹,

Barranco

et al. 2009

Phys. Rev. B

Self Cite

We investigate the effects ͑on the wetting characteristics of helium below 3 K͒ of tailoring an alkali-metal surface by incorporating a regular array of nanoscopic indentations. We establish the prewetting line of helium on semi-infinite planar Cs up to 3 K in the frame of a finite-range temperature-dependent density-functional theory, and examine the modifications introduced in the isotherms when the substrate is covered with a periodic lattice of parabolic cavities. We show that, both for the planar and nanostructured surfaces, the unstable regions of the isotherms are stabilized by nucleation of drops and/or bubbles. Results corresponding to nonwettable Cs surfaces are compared with those obtained both for planar and nanopatterned Na substrates, where wetting at zero temperature is instead expected to occur, for a planar surface, preceded by a first-order prewetting transition.

“…In particular, it has been shown that in addition to the well-known filling transition, which occurs as the liquidvapor interface becomes flat, an "emptying" transition preannouncing the formation of a bridge can take place for sufficiently narrow openings. Furthermore, the study of the adsorbed density profiles and their energetics has provided a reference frame for more involved analysis of the adsorption isotherms of helium in infinite pores 15 and on nanostructured surfaces. 16 Since these studies concentrate on the equilibrium properties of the confined fluid, it is natural to take one step forward and interrogate oneself about the low-energy collective excitations supported by such systems.…”

Section: Introductionmentioning

confidence: 99%

Hydrodynamical description of long-wavelength density fluctuations of helium in wedges

2010

Phys. Rev. B

Self Cite

The hydrodynamical model that has proven successful to describe excitations of superfluid helium in the bulk and adsorbed on planar surfaces, cylinders, and spheres is applied to investigate the long-wavelength density fluctuation spectrum of 4 He confined to an infinite linear wedge at zero temperature. It is found that in spite of the breaking of axial symmetry, the velocity potentials and the shape of the meniscus can be described in terms of an orbital quantum number or quasiangular momentum, and that the density wave spectrum is formally similar to that of helium shells adsorbed in a cylindrical pore. As an illustration, the stability of phonon and ripplon modes are discussed in terms of the relevant parameters of helium in a cesium wedge.