Main Catalog Physics Physics and technology of nanostructures, nuclear and molecular

The electron density distribution function for metallic nanoparticles within the framework of the theory of density functionals

Authors: Fedorova V.Yu.
Published in issue: #8(25)/2018
DOI: 10.18698/2541-8009-2018-8-355
Category: Physics \| Chapter: Physics and technology of nanostructures, nuclear and molecular
Keywords: density functional method, nanopowder, jelly model, electron density, variational method, Friedel oscillations, Schrödinger equation, potential well
Published: 07.08.2018

The paper presents the choice of the trial electron density function in the framework of the density functional theory for the jelly model describing a system consisting of spherically symmetric aluminum nanoparticles. The effect that occurs near the metal-environment boundary associated with Friedel oscillations is taken into account. The conditions for the possibility of using a given function for further calculations of the surface energy, work function, and other characteristics of the nanopowder of a given metal are set. Within the framework of the variational method, numerical calculations of the necessary coefficients and variational parameters for different radii of nanoparticles are given, taking into account the average electron density of aluminum used for subsequent calculations of energy characteristics.

References

[1] Kohn V. Electron material structure – wave functions and density functional. UFN, 2002, vol. 172, no. 3, pp. 336–348.

[2] Partenskiy M.B. Self-consistent electron theory of a metallic surface. UFN, 1979, vol. 128, no. 5, pp. 69–106. (Eng. version: Sov. Phys. Usp., 1979, vol. 22, no. 3, pp. 330–351.)

[3] Satanin A.M. Vvedenie v teoriyu funktsionala plotnosti [Introduction to density functional theory]. Nizhniy Novgorod, UNN publ., 2009, 64 p.

[4] Smith J.R. Self-consistent many-electron theory of electron work functions and surface potential characteristics for selected metals. Physical Review, 1969, vol. 181, no. 2, pp. 522–529.

[5] Kiejna A., Wojciechowski K.F. Metal surface electron physics. Pergamon, 1996, 312 p.

[6] Sarkisov P.D., Baykov Yu.A., Meshalkin V.P. Self-consisted field method in Hartree approximation of two-electron systems for different electron configurations. Doklady akademii nauk, 2008, vol. 423, no. 3, pp. 331–335.

[7] Mayer I. Simple theorems, proofs and derivations in quantum chemistry. Springer, 2003, 337 p.

[8] Glushkov V.L., Erkovich O.S. Surface characteristics of alkali metals with the discrete lattice and Friedel oscillations of the electron density. Vestn. Mosk. Gos. Tekh. Univ. im. N.E. Baumana, Estestv. Nauki [Herald of the Bauman Moscow State Tech. Univ., Nat. Sci.], 2017, no. 4, pp. 75–89.

[9] Mamonova M.V., Bartysheva M.A. Description of the influence of the Friedel oscillations in the calculation of the distribution of electron density and the surface energy of metals. Vestnik Omskogo universiteta [Herald of Omsk University], 2010, no. 2, pp. 39–43.

[10] Chaplik A.V., Kovalev V.M., Magarill L.I., Vitlina R.Z. Electrostatic screening and Friedel oscillations in nanostructures. Journal of superconductivity and novel magnetism, 2012, vol. 25, no. 3, pp. 699–709.