Monte Carlo analysis of an interatomic potential for He

Boronat, J.; Casulleras, J.

doi:10.1103/physrevb.49.8920

Cited by 224 publications

(238 citation statements)

References 33 publications

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“…4, we also compare our estimates for n 0 with the experimental ones 6 and with the ones obtained in previous numerical simulations. [9][10][11]13 It is easy to notice that our results provide an excellent description of the experimental dependence of the condensate fraction as a function of pressure in all the range of stability of the liquid phase of 4 He, improving previous calculations which focus especially on the equilibrium density and do not explore in detail the physically interesting pressure range where the experimental data can be measured. Notice that the experimental value of n 0 at zero pressure reported in the more recent experiment 6 is slightly smaller (7.01 ± 0.75%), but still statistically compatible within the error bars, than the previous one by the same team.…”

Section: Resultsmentioning

confidence: 68%

“…At the equilibrium density of liquid 4 4 He at zero temperature as a function of pressure p in the region of stability of liquid phase. Our PIGS results (black squares) are compared with the experimental ones (red diamonds) 6 and previous theoretical calculations, obtained with Diffusion Monte Carlo (green up triangles), 10 Diffusion Euler Monte Carlo (violet left triangles), 11 Reptation Quantum Monte Carlo (blue circle) 13 and PIMC at T = 1 K. 9 The dashed line represents the curve obtained fitting our results with the equation…”

Section: Discussionmentioning

confidence: 99%

“…Diffusion Monte Carlo technique, for instance, has provided estimations of n 0 in liquid 4 He on a wide range of pressures. [10][11][12] This method, however, suffers from the choice of a variational ansatz necessary for the importance sampling whose influence on ρ 1 (r) cannot be completely removed. Reptation Quantum Monte Carlo (RQMC) has also been used for this purpose, 13 but the calculated value of n 0 at SVP lies somewhat below the recent PIMC value 9 at T = 1 K noted above.…”

Section: Introductionmentioning

confidence: 99%

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Condensate Fraction in Liquid 4He at Zero Temperature

Rota

Boronat

2011

J Low Temp Phys

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We present results of the one-body density matrix ρ 1 (r) and the condensate fraction n 0 of liquid 4 He calculated at zero temperature by means of the Path Integral Ground State Monte Carlo method. This technique allows to generate a highly accurate approximation for the ground state wave function Ψ 0 in a totally model-independent way, that depends only on the Hamiltonian of the system and on the symmetry properties of Ψ 0 . With this unbiased estimation of ρ 1 (r), we obtain precise results for the condensate fraction n 0 and the kinetic energy K of the system. The dependence of n 0 with the pressure shows an excellent agreement of our results with recent experimental measurements. Above the melting pressure, overpressurized liquid 4 He shows a small condensate fraction that has dropped to 0.8% at the highest pressure of p = 87 bar.

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Section: Resultsmentioning

confidence: 68%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Condensate Fraction in Liquid 4He at Zero Temperature

Rota

Boronat

2011

J Low Temp Phys

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“…The DMC algorithm is nowadays a standard tool that provides exact results when solving the N -body Schrödinger equation for boson systems within some statistical errors. It does so by the introduction of an importance sampling strategy through a guiding wave function Ψ [15]. For the liquid phases studied in this work we have used…”

Section: Methodsmentioning

confidence: 99%

Phase Diagrams of 4He on Flat and Curved Environments

Gordillo

Boronat

2012

J Low Temp Phys

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By means of diffusion Monte Carlo calculations, we obtained the phase diagrams of a first and second layer of 4 He on graphene and on the outside of different isolated armchair carbon nanotubes with radii in the range 3.42 to 10.85 Å. That corresponds to tubes between the (5, 5) and (16, 16) in standard nomenclature. In both cases, the ground state is either a liquid (second layer on graphene and on nanotubes whose radii is greater than ∼7 Å) or an incommensurate solid (for thinner tubes). In the former case, upon a density increase, the system undergoes a first-order phase transition to another incommensurate solid. A study of the influence of the C-He potential (isotropic or anisotropic) on the phase diagrams is also presented.

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“…Furthermore, we test their halo nature. In the next Section, we introduce the diffusion Monte Carlo method (DMC) 31 and discuss the trial wave functions used for importance sampling. After results are discussed and compared with other theoretical works, we comprise a summary of the work and an account of the main conclusions.…”

Section: Introductionmentioning

confidence: 99%

Quantum Halo States in Helium Tetramers

2016

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Universality of quantum halo states enables comparison of systems from different fields of physics, as demonstrated in two-and three-body clusters. In the present work, we studied weakly-bound helium tetramers in order to test whether some of these four-body realistic systems qualify as halos. Their ground-state binding energies and structural properties were thoroughly estimated using the diffusion Monte Carlo method with pure estimators. Helium tetramer properties proved to be less sensitive on the potential model than previously evaluated trimer properties. We predict the existence of the realistic four-body halo 4 He 2 3 He 2 , while 4 He 4 and 4 He 3 3 He are close to the border and thus can be used as prototypes of quasi-halo systems. Our results could be tested by experimental determination of tetramers' structural properties, using a similar setup to the one developed for the study of helium trimers.

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Monte Carlo analysis of an interatomic potential for He

Cited by 224 publications

References 33 publications

Condensate Fraction in Liquid 4He at Zero Temperature

Condensate Fraction in Liquid 4He at Zero Temperature

Phase Diagrams of 4He on Flat and Curved Environments

Quantum Halo States in Helium Tetramers

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