Finite-size effects and the stabilized spin-polarized jellium model for metal clusters

Payami, M.

doi:10.1063/1.480175

Cited by 9 publications

(10 citation statements)

References 28 publications

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“…1 we have compared the equilibrium r s values of "generic clusters", JM1 (see Ref. 10), with the SJM1 results which reproduce correct trends. [12] To clarify the concept of the "generic cluster", suppose that one solves the self-consistent KS-LSDA equations for a spherical simple JM cluster with jellium radius equal to R = N 1/3 r s and total number of electrons N. For a given N, these calculations are performed for different r s values as well as different spin configurations until the equilibrium r s value,r s (N, ζ), corresponding to the absolute minimum-energy configuration is obtained ( See Fig.…”

Section: Resultsmentioning

confidence: 87%

“…We have recently shown [10] that it is not always necessary for a finite spherical jellium system to increase its size as the polarization, ζ, is increased. This can be explained by considering the fact that for an open-shell cluster if one increases the spin polarization from the possible minimum value consistent with the Pauli exclusion principle, one should make a spin-flip in the last uncomplete shell.…”

Section: Introductionmentioning

confidence: 99%

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Equilibrium Sizes of Jellium Metal Clusters in the Stabilized Spin-Polarized Jellium Model

Payami

2001

phys. stat. sol. (b)

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Subject classification: 71.15. Dx; 71.15.Mb; 71.15.Nc We have used the stabilized spin-polarized jellium model to calculate the equilibrium sizes of metal clusters. Our self-consistent calculations in the local spin-density approximation show that for an N-electron cluster, equilibrium is achieved for a configuration in which the difference in the numbers of up-spin and down-spin electrons is zero or unity, depending on the total number of electrons. That is, a configuration in which the spins are maximally compensated. This maximum spin compensation results in both the alternation in the average distance between the nearest-neighbor ions and the odd-even alternations in the ionization energies of alkali metal clusters, in good agreement with the molecular dynamics findings and the experiment. These suggest a realistic and more accurate method for calculating the properties of metal clusters in the context of jellium model than previous jellium model methods.

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Section: Resultsmentioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Equilibrium Sizes of Jellium Metal Clusters in the Stabilized Spin-Polarized Jellium Model

Payami

2001

phys. stat. sol. (b)

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“…This effect is called self-expansion. The self-expansion has been also predicted for highly polarized metal clusters 17,23 . These two effects have different origins.…”

Section: Introductionmentioning

confidence: 92%

Fragmentation of Positively Charged Metal Clusters in Stabilized Jellium Model With Self-Compression

Payami¹

2004

Physics and Technology of Thin Films

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Using the stabilized jellium model with self-compression, we have calculated the dissociation energies and the barrier heights for the binary fragmentation of charged silver clusters. At each step of calculations, we have used the relaxed-state sizes and energies of the clusters. The results for the doubly charged Ag clusters predict a critical size, at which evaporation dominates the fission, in good agreement with the experiment. Comparing the dissociation energies and the fission barrier heights with the experimental ones, we conclude that in the experiments the fragmentation occurs before the full structural relaxation expected after the ionization of the cluster. In the decays of Ag 4+ N clusters, the results predict that the charge-symmetric fission processes are dominant for smaller clusters, and the charge-asymmetric fission processes become dominant for sufficiently larger clusters. * This work is dedicated to the memory of my mother, Gohar and the 68 th birthday of my father, Bahram.

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“…29. It provides a useful zero-order model for bulk 2 and surface properties, 30 cohesive and vacancy-formation energies, 31,32 and size effects in clusters 33,34 and thin films. 35 Its relationship to other simple models such as the ''ideal metal'' 36 has been discussed in Ref.…”

Section: Stabilized Jellium Model and Stabilized Jellium Equatiomentioning

confidence: 99%

Energy and pressure versus volume: Equations of state motivated by the stabilized jellium model

et al. 2001

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Explicit functions are widely used to interpolate, extrapolate, and differentiate theoretical or experimental data on the equation of state ͑EOS͒ of a solid. We present two EOS functions which are theoretically motivated. The simplest realistic model for a simple metal, the stabilized jellium ͑SJ͒ or structureless pseudopotential model, is the paradigm for our SJEOS. A simple metal with exponentially overlapped ion cores is the paradigm for an augmented version ͑ASJEOS͒ of the SJEOS. For the three solids tested ͑Al, Li, Mo͒, the ASJEOS matches all-electron calculations better than prior equations of state. Like most of the prior EOS's, the ASJEOS predicts pressure P as a function of compressed volume v from only a few equilibrium inputs: the volume v 0 , the bulk modulus B 0 , and its pressure derivative B 1. Under expansion, the cohesive energy serves as another input. A further advantage of the new equation of state is that these equilibrium properties other than v 0 may be found by linear fitting methods. The SJEOS can be used to correct B 0 and the EOS found from an approximate density functional, if the corresponding error in v 0 is known. We also ͑a͒ estimate the typically small contribution of phonon zero-point vibration to the EOS, ͑b͒ find that the physical hardness Bv does not maximize at equilibrium, and ͑c͒ show that the ''ideal metal'' of Shore and Rose is the zero-valence limit of stabilized jellium.

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Finite-size effects and the stabilized spin-polarized jellium model for metal clusters

Cited by 9 publications

References 28 publications

Equilibrium Sizes of Jellium Metal Clusters in the Stabilized Spin-Polarized Jellium Model

Equilibrium Sizes of Jellium Metal Clusters in the Stabilized Spin-Polarized Jellium Model

Fragmentation of Positively Charged Metal Clusters in Stabilized Jellium Model With Self-Compression

Energy and pressure versus volume: Equations of state motivated by the stabilized jellium model

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