Discrete charge dielectric model of electrostatic energy

LaFave, Tim

doi:10.1016/j.elstat.2011.06.006

Cited by 8 publications

(8 citation statements)

References 12 publications

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“…3 as the unit Thomson radius constraint is relaxed to minimize the sum of all electrostatic interaction terms within the sphere. 18 This suggests that a screening parameter is important to future developments as it is involved in the spherical jellium model 48 which presumes a "uniform" positive background charge within a spherical volume (cf. the "plum pudding" model) to neutralize the total charge of the system.…”

Section: Discussionmentioning

confidence: 99%

“…2 Recently, similarities between classical electrostatic properties of spherical quantum dots and the distribution of empirical ionization energies of neutral atoms were reported for N ≤ 32 electrons 16,17 when evaluated using the discrete charge dielectric model. 18 The present paper builds on this previous work by identifying numerous correspondences between the electrostatic Thomson Problem of distributing equal point charges on a unit sphere and atomic electronic structure.…”

Section: Introductionmentioning

confidence: 87%

“…Energies inFig. 3 associated with N =4,10,12,18,20,30,36,48, 54, 56, 70, 80, and 88 exhibit this trait. The few exceptions to this trend, N =2, 38, and 86, are indiscernible from the rising global trend of the distribution.…”

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confidence: 89%

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Correspondences between the classical electrostatic Thomson problem and atomic electronic structure

LaFave

2013

Journal of Electrostatics

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Correspondences between the Thomson Problem and atomic electron shell-filling patterns are observed as systematic non-uniformities in the distribution of potential energy necessary to change configurations of N ≤ 100 electrons into discrete geometries of neighboring N − 1 systems. These non-uniformities yield electron energy pairs, intra-subshell pattern similarities with empirical ionization energy, and a salient pattern that coincides with size-normalized empirical ionization energies. Spatial symmetry limitations on discrete charges constrained to a spherical volume are conjectured as underlying physical mechanisms responsible for shell-filling patterns in atomic electronic structure and the Periodic Law.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 87%

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Correspondences between the classical electrostatic Thomson problem and atomic electronic structure

LaFave

2013

Journal of Electrostatics

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“…In case of discrete charge elements, d q = e , the quantum capacitance expression would be in order, which refers either to the right- or to the left-hand side process (to one electron charge increment or deduction) and has been advocated to come without one-half factor . Nevertheless, the quantity given here has the self-capacitance nature, and it is based on continuum inhomogeneous charge distribution, to which the one-half formalism applies , (similarly, as it occurs in the textbook integration approach to classical charging energy). Hence, by analogy to classical charging energy and in compliance with functional differentiation (variational derivative of energy with respect to density), the local capacitance is expressed as In a very straightforward model, the “chemical energy” in atoms or molecules is stored in the electric field, generated by electric charge (similarly to the macroscopic capacitors).…”

Section: Theorymentioning

confidence: 99%

Capacitance, the Next of Kin to Chemical Softness and Density of States, an Unexpected Perk of Being the “Middle Child”

Szarek

2016

J. Phys. Chem. C

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The capacitance characterizes abilities of various systems to store energy in the form of energy density of electric field. The spatial distribution of electrons exhibits a nonuniform relationship with external potential of atomic nuclei as a consequence of shielding or bonding, and other localized or delocalized charges. Respectively, the stored system energy is affected through thermodynamic displacement. Considering the general resemblance of capacitance definition with two other physical quantities used in the field of chemical physics, the chemical softness or the density of states, it is important to uniquely express this function in nanoscale materials to characterize phenomena resulting from confinement of few electrons generally characterized by density distribution. The exact fundamental linkages and differences between these functions have to be recognized to deal with unintuitive quantum mechanical effects related to the design, development, and comprehending the working principle of nanoscale materials and devices. The locally defined self-capacitance in atomic resolution systems is addressed here to draw the essential links between reactivity and physically observed properties resulting from the energy dispersion or entropy effects in molecular materials.

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“…The Thomson Problem treated within a dielectric sphere, (20)(21)(22) using an appropriate model for discrete charges in the presence of dielectrics (24) these disparities become more pronounced as shown in Fig. 5 (solid circles).…”

Section: Correspondence With Atomic Structurementioning

confidence: 99%

Discrete transformations in the Thomson Problem

LaFave

2014

Journal of Electrostatics

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A significantly lower upper limit to minimum energy solutions of the electrostatic Thomson Problem is reported. A point charge is introduced to the origin of each N -charge solution. This raises the total energy by N as an upper limit to each (N + 1)-charge solution. Minimization of energy to U (N + 1) is well fit with −0.5518(3/2) √ N + 1/2 for up to N =500. The energy distribution due to this displacement exhibits correspondences with shell-filling behavior in atomic systems. This work may aid development of more efficient and innovative numerical search algorithms to obtain N -charge configurations having global energy minima and yield new insights to atomic structure.

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Discrete charge dielectric model of electrostatic energy

Cited by 8 publications

References 12 publications

Correspondences between the classical electrostatic Thomson problem and atomic electronic structure

Correspondences between the classical electrostatic Thomson problem and atomic electronic structure

Capacitance, the Next of Kin to Chemical Softness and Density of States, an Unexpected Perk of Being the “Middle Child”

Discrete transformations in the Thomson Problem

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