Density functional theory of the structure of magnesium-doped helium nanodroplets

Hernando, Alberto; Barranco, M.; Mayol, R.; Pí, M.; Ancilotto, Francesco

doi:10.1103/physrevb.78.184515

Cited by 53 publications

(58 citation statements)

References 52 publications

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“…These apparently contradictory findings were reconciled by density functional theory calculations, which show that although Mg becomes fully solvated in sufficiently large helium droplets (>200 helium atoms), the energy lowering delivered by full solvation is relatively modest. 19 As a consequence, Mg is highly delocalized within the helium droplet and therefore has the opportunity to occasionally explore the subsurface region. This dual nature of the Mg atoms, in which they show both interior and near-surface behavior, accounts for the experimental findings.…”

Section: A Surface-to-submersion Transitionmentioning

confidence: 99%

Submersion of potassium clusters in helium nanodroplets

et al. 2012

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Small alkali clusters do not submerge in liquid helium nanodroplets but instead survive predominantly in high spin states that reside on the surface of the nanodroplet. However, a recent theoretical prediction by Stark and Kresin [Phys. Rev. B 81, 085401 (2010)], based on a classical description of the energetics of bubble formation for a fully submerged alkali cluster, suggests that the alkali clusters can submerge on energetic grounds when they exceed a critical size. Following recent work on sodium clusters, where ion yield data from electron impact mass spectrometry was used to obtain the first experimental evidence for alkali cluster submersion, we report here on similar experiments for potassium clusters. Evidence is presented for full cluster submersion at n > 80 for K n clusters, which is in good agreement with the recent theoretical prediction. In an additional observation, we report "magic number" sizes for both K n + and K n 2+ ions derived from helium droplets, which are found to be consistent with the jellium model.

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Section: A Surface-to-submersion Transitionmentioning

confidence: 99%

Submersion of potassium clusters in helium nanodroplets

et al. 2012

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“…It makes use of the Franck-Condon principle within a semiclassical approach. It has been adapted and used by several authors to analyze the absorption spectrum of e.g., lithium in solid H 2 [40], and of different atoms in helium clusters [41,42,43,45]. The particular case of Ca atoms we are interested in has been addressed within DF in pure and mixed helium clusters [12,43].…”

Section: Resultsmentioning

confidence: 99%

Ca impurity in small mixed H4e–H3e clusters

Guardiola

Navarro

Mateo

et al. 2009

The Journal of Chemical Physics

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The structure of small mixed helium clusters doped with one calcium atom has been determined within the diffusion Monte Carlo framework. The results show that the calcium atom sits at the 4 He-3 He interface. This is in agreement with previous studies, both experimental and theoretical, performed for large clusters. A comparison between the results obtained for the largest cluster we have considered for each isotope shows a clear tendency of the Ca atom to reside in a deep dimple at the surface of the cluster for 4 He clusters, and to become fully solvated for 3 He clusters. We have calculated the absorption spectrum of Ca around the 4s4p ← 4s 2 transition and have found that it is blue-shifted from that of the free-atom transition by an amount that depends on the size and composition of the cluster.

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“…Due to the light mass of this alkaline earth atom and its weak interaction with helium, Mg impurities are found to be very delocalized inside droplets containing several thousand 4 He atoms, 13 as those of interest in recent experiments. 18,19 In the case of 3 He, we have found that Mg is always in the bulk of the 3 He droplet, as determined by previous DFT calculations.…”

Section: Discussionmentioning

confidence: 99%

“…A similar transition from surface to bulk location of Mg was also found within DFT. 13 This paper is organized as follows. In Sec.…”

Section: Introductionmentioning

confidence: 99%

“…Within Density Functional Theory (DFT), it has been found to solvate in 3 He droplets and to be very delocalized in 4 He ones. 10,13 Previous diffusion Monte Carlo calculations (DMC) 14 have yielded the result that Mg is fully solvated for a critical number of 4 He atoms of about N 4 = 30. A similar transition from surface to bulk location of Mg was also found within DFT.…”

Section: Introductionmentioning

confidence: 99%

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Mg impurity in helium droplets

Navarro

Mateo

Barranco

et al. 2012

The Journal of Chemical Physics

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Within the diffusion Monte Carlo approach, we have determined the structure of isotopically pure and mixed helium droplets doped with one magnesium atom. For pure 4 He clusters, our results confirm those of M. Mella et al. [J. Chem. Phys. 123, 054328 (2005)] that the impurity experiences a transition from a surface to a bulk location as the number of helium atoms in the droplet increases. Contrarily, for pure 3 He clusters Mg resides in the bulk of the droplet due to the smaller surface tension of this isotope. Results for mixed droplets are presented. We have also obtained the absorption spectrum of Mg around the 3s3p 1 P 1 ← 3s 2 1 S 0 transition.

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Density functional theory of the structure of magnesium-doped helium nanodroplets

Cited by 53 publications

References 52 publications

Submersion of potassium clusters in helium nanodroplets

Submersion of potassium clusters in helium nanodroplets

Ca impurity in small mixed H4e–H3e clusters

Mg impurity in helium droplets

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