A simple semiempirical model for the static polarizability of electronically excited atoms and molecules

Abstract: We present a semiempirical analytical model for the static polarizability of electronically excited atoms and molecules that requires very few readily accessible input data, including the ground-state polarizability, elemental composition, ionization potential, and spin multiplicities of excited and ground states. This very simple model formulated in a semiclassical framework is based on a number of observed trends in polarizability of electronically excited compounds. To adjust the model, both accurate theore… Show more

“…[84] In fact, there is an inverse power-function relationship between α n and N out in a given row, with the magnitude of the corresponding exponent ranging significantly (from 3 to 9). [13] However, for more accurate analytical representation of this "horizontal" trend, following Cambi et al, [158] the effective number of outer-shell electrons N eff out is to be used instead of N out to account for the additional influence of the inner-shell (core) electrons, the number of which we denote as N inn (see also reference [15] for related discussion). In doing so, for the elements starting with Li, the N eff out values can be calculated as follows:…”

“…[1][2][3][4][5][6][7] However, accurate experimental and theoretical data for this pivotal electric property are widely available mainly for neutral atomic and molecular species. [6][7][8][9][10][11][12][13][14][15] As for ions, the reliable literature values are predominately limited to singly and doubly charged monoatomic cations, [16][17][18][19][20][21][22][23] whereas both for highly charged atomic cations and especially for anions (both atomic and molecular) there is a lack of established data on polarizability. Indeed, the information available in the literature on the isotropic (scalar) polarizability values for multiply charged atomic species is essentially fragmentary, [16,21,22,[24][25][26] and the polarizability estimates for negative monoatomic ions reported elsewhere can differ by tens of percent and even several times.…”

A simple semiempirical model for the static polarizability of ions

“…[84] In fact, there is an inverse power-function relationship between α n and N out in a given row, with the magnitude of the corresponding exponent ranging significantly (from 3 to 9). [13] However, for more accurate analytical representation of this "horizontal" trend, following Cambi et al, [158] the effective number of outer-shell electrons N eff out is to be used instead of N out to account for the additional influence of the inner-shell (core) electrons, the number of which we denote as N inn (see also reference [15] for related discussion). In doing so, for the elements starting with Li, the N eff out values can be calculated as follows:…”

“…[1][2][3][4][5][6][7] However, accurate experimental and theoretical data for this pivotal electric property are widely available mainly for neutral atomic and molecular species. [6][7][8][9][10][11][12][13][14][15] As for ions, the reliable literature values are predominately limited to singly and doubly charged monoatomic cations, [16][17][18][19][20][21][22][23] whereas both for highly charged atomic cations and especially for anions (both atomic and molecular) there is a lack of established data on polarizability. Indeed, the information available in the literature on the isotropic (scalar) polarizability values for multiply charged atomic species is essentially fragmentary, [16,21,22,[24][25][26] and the polarizability estimates for negative monoatomic ions reported elsewhere can differ by tens of percent and even several times.…”

A simple semiempirical model for the static polarizability of ions